Utilization of UF-permeate for production of beta-galactosidase by lactic acid bacteria

Four lactobacilli strains (Lactobacillus bulgaricus, Lactobacillus acidophilus, Lactobacilus casei and Lactobacillus reuteri) were grown in MRS broth and three lactococci strains (Streptococcus thermophilus, Lactococcus lactis subsp. Lactis and Lactococcus lactis subsp. lactis biovar. diacetilactis) were grown in M17 broth. L. reuteri and S. thermophilus were chosen on the basis of the best mean beta-galactosidase activity of 10.44 and 10.01 U/ml respectively, for further studies on permeate-based medium. The maximum production of beta-galactosidase by L. reuteri was achieved at lactose concentration of 6%, initial pH 5.0-7.5, ammonium phosphate as nitrogen source at a concentration of 0.66 g N/L and incubation temperature at 30 degrees C/24 hrs to give 6.31 U/ml. While in case of S. thermophilus, maximum beta-galactosidase production was achieved at 10% lactose concentration of permeate medium, supplemented with phosphate buffer ratio of 0.5:0.5 (KH2PO4:K2HPO4, g/L), at initial pH 6.0-6.5, ammonium phosphate (0.66g N/L) as nitrogen source and incubation temperature 35 degrees C for 24 hrs to give 7.85 U/ml.     

Growth Stimulation of Lactobacillus Species by Lactic Streptococci

Cell extracts of Streptococcus species important in cheese starters stimulated the growth of Lactobacillus species common to Cheddar cheese. All Lactobacillus strains employed, with the exception of a strain of L. casei, were significantly stimulated by a strain of S. diacetilactis. L. casei was highly stimulated by both a strain of S. lactis and a strain of S. diacetilactis. The stimulant(s) was dialyzable and was partially inactivated by heat. The stimulatory principle was active at 10 C, indicating that the stimulatory effect may be influencing the growth of lactobacilli in Cheddar cheese during curing. Viable Streptococcus cells did not inhibit the growth of Lactobacillus species.     

Long-Term Storage of Bacteriophages of Lactic Streptococci

Four phage strains representing phages of Streptococcus lactis, S. cremoris, and S. diacetilactis were selected for the observation of the effect of cold storage on their viability. Phages were stored at 4 C and at -18 C, or were frozen at approximately -70 C and stored at -18 C. They were found to display a high degree of stability with these storage methods. The same phage strains showed good stability to storage at room temperature for 3 weeks after thawing and also to alternate freezing and thawing eight times. Three series consisting of from 23 to 31 lactic streptococcal phage preparations were observed over periods extending up to 6 years, and with only a few exceptions were found to store satisfactorily at -18 C after quick freezing. Although the same phage preparations stored at 4 C were generally somewhat less stable, many were stable when stored by both methods.     

Lysogeny in Lactic Streptococci Producing and Not Producing Nisin

Eighty-seven strains of lactic streptococci (46 of Streptococcus lactis, 24 of S. diacetilactis, and 17 of S. cremoris) were tested for lysogeny; 12 S. lactis strains produced nisin. Lysogeny was found in five S. lactis strains (two of them were nisin producers) and in two S. diacetilactis strains. Four S. lactis and two S. diacetilactis lysogens liberated phages both spontaneously and after ultraviolet treatment, and one S. lactis strain liberated phages spontaneously only. No lysogens were found among the S. cremoris strains tested. An initial characterization of the lysogens and their phages was made. The lytic spectrum of some of the examined phages was very narrow (homospecific), whereas that of others was wide, including strains of the three investigated species.     

Identification of lactose fermentation plasmids of streptococcal dairy starter strains by Southern hybridization

Twenty-two strains of Streptococcus cremoris , seven strains of Streptococcus lactis and three strains of Streptococcus lactis subsp. diacetilactis, each with a different plasmid complement, were isolated from a starter culture used in a Finnish dairy plant. By using DNA-DNA hybridization, with cloned 6-P-ß-galactosidase gene of the Strep, lactis plasmid pLP712 as a probe, the lactose fermentation genes were located, in each strain, in the large ( 30 MD) plasmid.     

Loss of Lactose Metabolism in Lactic Streptococci

Lactose-negative mutants occurred spontaneously in broth cultures of Streptococcus lactis C(2)F. Instability of lactose metabolism was noted in other strains of S. lactis, in strains of S. cremoris, and in S. diacetilactis. Colonies of S. lactis C(2)F grown with lactose as the carbohydrate source also possessed lac(-) cells. Treatment of lactic streptococci with the mutagen acriflavine (AF) increased the number of non-lactose-fermenting variants. The effect of AF on growth and on loss of lactose-fermenting ability in S. lactis C(2)F was consequently further examined. The presence of AF appears to favor competitively the growth of spontaneously occurring lactose-negative cells and appears to act in the conversion of lactose-positive to non-lactose-fermenting cells. The lactose-negative mutants partially revert to lactose-positive variants which remain defective in lactose metabolism and remain unable to coagulate milk. The lactose-negative cells become dominant in continuous culture growth and provide evidence that alterations in the characteristics of starter strains can be produced by continuous culture, in this case, the complete loss in ability to ferment lactose.     

Simultaneous Loss of Proteinase- and Lactose-Utilizing Enzyme Activities in Streptococcus lactis and Reversal of Loss by Transduction

During studies on spontaneous loss of lactose metabolism in Streptococcus lactis C2, it was found that the lactose-negative (lac(-)) mutants were also proteinase negative (prt(-)). This pleiotropic effect was observed in S. diacetilactis 18-16, but not in S. cremoris B1. The lac(-)prt(-) mutants from S. lactis C2 were able to grow in milk, but no pH change or measurable protein breakdown occurred. When the milk was supplemented with glucose, a slow decline in pH occurred. Addition of a protein hydrolysate to milk did not stimulate acid production. When both supplements were added to milk, normal growth and pH change were obtained. When the lac(-)prt(-) mutant of S. lactis C2 was transduced with the temperate phage from the lac(+)prt(+) parent culture, approximately equal numbers of lac(+)prt(-) and lac(+)prt(+) transductants were obtained. When the spontaneous lac(+)prt(-) strain of S. lactis C2 was converted to a lac(-)prt(-) derivative and transduced, similar results were obtained. The co-transduction of the lactose and proteinase markers suggest they are closely associated. The findings indicate that the transducing phage from S. lactis C2 can be used to examine the causes of instability in both the lactose and proteinase enzyme systems of this organism.     

Molecular and physiological characterization of dominant bacterial populations in traditional mozzarella cheese processing

The development of the dominant bacterial populations during traditional Mozzarella cheese production was investigated using physiological analyses and molecular techniques for strain typing and taxonomic identification. Analysis of RAPD fingerprints revealed that the dominant bacterial community was composed of 25 different biotypes, and the sequence analysis of 16S rDNA demonstrated that the isolated strains belonged to Leuconostoc mesenteroides subsp. mesenteroides , Leuc. lactis , Streptococcus thermophilus , Strep. bovis , Strep. uberis, Lactococcus lactis subsp. lactis , L. garviae, Carnobacterium divergens , C. piscicola, Aerococcus viridans , Staphylococcus carnosus, Staph. epidermidis , Enterococcus faecalis , Ent. sulphureus and Enterococcus spp. The bacterial populations were characterized for their physiological properties. Two strains, belonging to Strep. thermophilus and L. lactis subsp. lactis , were the most acidifying; the L. lactis subsp. lactis strain was also proteolytic and eight strains were positive to citrate fermentation. Moreover, the molecular techniques allowed the identification of potential pathogens in a non-ripened cheese produced from raw milk.     

Lysogenic strains of lactic Acid streptococci and lytic spectra of their temperate bacteriophages

A total of 113 strains of mesophilic strains lactic streptococci of the species Streptococcus lactis, S. lactis subsp. diacetilactis, and S. cremoris, chosen from 291 strains that had been previously classified into six groups on the basis of their sensitivity to 132 virulent phages, were subjected to induction with mitomycin C. Among these strains, 43% produced phages capable of forming plaques of lysis on an indicator strain either spontaneously or after induction. There was a close correlation between the lytic spectra of temperate and virulent phages. Among the strains studied, 25% were shown to be indicator strains. These results emphasized the high probability of development of temperate phages in a starter culture containing mesophilic lactic streptococci and therefore their importance as a cause of accidents in cheese making.     

Proteinase Activity in Slow Lactic Acid-Producing Variants of Streptococcus lactis

Variants of Streptococcus lactis that produce lactic acid slowly in milk were isolated by inducing plasmid loss in the wild type at 39 to 40 C. Such strains had lost most of their surface-bound proteinase activity and were designated prt(-). The specific proteinase activities of S. lactis C10 prt(+) whole cells and solubilized cell walls were 7 and 18 times, respectively, those of the prt(-) strain, but spheroplast lysates of prt(+) and prt(-) strains contained similar proteinase activity. S. lactis H1 showed a similar relative distribution of activity between prt(+) and prt(-) cellular fractions, although the overall level was lower. The limited growth in milk, characteristic of prt(-) strains, can be explained in terms of their low surface-bound proteinase activity.     

Occurence of lactose-negative mutants in chemostat cultures of lactic streptococci.

Batch and chemostat cultures of Streptococcus cremoris HP and Streptococcus lactis 829 were examined for lactose-hegative (lac-)mutants on indicator agar. In batch cultures, S. cremoris HP gave less than 1% of the total count as lac- colonies while S. lactis 829 consistently contained about 15% of the total as lac- colonies. In chemostat cultures of S. cremoris HP in 2% skim milk containing casamino acids and yeast extract (0.1% each), the percentage of lac- colonies increased markedly when the temperature of growth was 18 degrees C but not when the temperature of growth was 25 degrees C. The percentage of lac- colonies in chemostat cultures in the skim milk medium at 25 degrees C was about the same as that in batch cultures. On the other hand, when chemostat cultures of S. lactis 829 in the skim milk medium were grown at several temperatures between 18 and 33 degrees C, the percentage of lac- colonies was markedly lower than that found in batch cultures of this organism. Cultivation of S. cremoris HP in chemostats with yeast extract-glucose broth at low temperature (18 degrees C) resulted in a selection of cells giving lac- colonies and atypical (small) lac+ colonies. The results show that cultivation of S. cremoris HP and S. lactis 829 in chemostats sometimes gave rise to altered populations. Conditions causing a change in one organism did not necessarily cause a similar change in the other. The results indicate that the successful propagation of lactic streptococci in chemostats for use as starter cultures in the dairy industry will require the careful establishment of optimum conditions for every strain so as to minimize the possible selection of undesirable populations.     

Cloning and expression of a Streptococcus cremoris proteinase in Bacillus subtilis and Streptococcus lactis

Previously, curing experiments suggested that plasmid pWV05 (17.5 megadaltons [Md]) of Streptococcus cremoris Wg2 specifies proteolytic activity. A restriction enzyme map of pWV05 was constructed, the entire plasmid was subcloned in Escherichia coli with plasmids pBR329 and pACYC184. A 4.3-Md HindIII fragment could not be cloned in an uninterrupted way in E. coli but could be cloned in two parts. Both fragments showed homology with the 9-Md proteinase plasmid of S. cremoris HP. The 4.3-Md HindIII fragment was successfully cloned in Bacillus subtilis on plasmid pGKV2 (3.1 Md). Crossed immunoelectrophoresis of extracts of B. subtilis carrying the recombinant plasmid (pGKV500; 7.4 Md) showed that the fragment specifies two proteins of the proteolytic system of S. cremoris Wg2. PGKV500 was introduced in a proteinase-deficient Streptococcus lactis strain via protoplast transformation. Both proteins were also present in cell-free extracts of S. lactis(pGKV500). In S. lactis, pGKV500 enables the cells to grow normally in milk with rapid acid production, indicating that the 4.3-Md HindIII fragment of plasmid pWV05 specifies the proteolytic activity of S. cremoris Wg2.     

Cloning and expression of a Streptococcus cremoris proteinase in Bacillus subtilis and Streptococcus lactis.

Previously, curing experiments suggested that plasmid pWV05 (17.5 megadaltons [Md]) of Streptococcus cremoris Wg2 specifies proteolytic activity. A restriction enzyme map of pWV05 was constructed, the entire plasmid was subcloned in Escherichia coli with plasmids pBR329 and pACYC184. A 4.3-Md HindIII fragment could not be cloned in an uninterrupted way in E. coli but could be cloned in two parts. Both fragments showed homology with the 9-Md proteinase plasmid of S. cremoris HP. The 4.3-Md HindIII fragment was successfully cloned in Bacillus subtilis on plasmid pGKV2 (3.1 Md). Crossed immunoelectrophoresis of extracts of B. subtilis carrying the recombinant plasmid (pGKV500; 7.4 Md) showed that the fragment specifies two proteins of the proteolytic system of S. cremoris Wg2. PGKV500 was introduced in a proteinase-deficient Streptococcus lactis strain via protoplast transformation. Both proteins were also present in cell-free extracts of S. lactis(pGKV500). In S. lactis, pGKV500 enables the cells to grow normally in milk with rapid acid production, indicating that the 4.3-Md HindIII fragment of plasmid pWV05 specifies the proteolytic activity of S. cremoris Wg2.     

Isolation, screening and characterization of bacteriocin-producing lactic acid bacteria isolated from traditional fermented food

100 lactic acid bacterial strains isolated from traditional fermented foods (yoghurt, milk cream, sour dough and milk) were screened for bacteriocin production. Twenty six strains producing a nisin-like bacteriocin were selected. Most of these isolates gave only a narrow inhibitory spectrum, although one showed a broad inhibitory spectrum against the indicator strains tested, this strain was determined as Lactococcus lactis. The influence of several parameters on the fermentative production of nisin by Lactococcus lactis was studied. Production of nisin was optimal at 30 degrees C and in the pH range 5.5-6.3. The effect of different sulphur and nitrogen sources on Lactococcus lactis growth and nisin production was studied. Magnesium sulfate and manganese sulfate were found to be the best sulphur sources while triammonium citrate was the best inorganic nitrogen source and meat extract, peptone and yeast extract were the best organic nitrogen source for nisin production.     

Detection and activity of lactacin B, a bacteriocin produced by Lactobacillus acidophilus

A total of 52 strains of Lactobacillus acidophilus were examined for production of bacteriocins. A majority (63%) demonstrated inhibitory activity against all members of a four-species grouping of Lactobacillus leichmannii, Lactobacillus bulgaricus, Lactobacillus helveticus, and Lactobacillus lactis. Four L. acidophilus strains with this activity also inhibited Streptococcus faecalis and Lactobacillus fermentum, suggesting a second system of antagonism. Under conditions eliminating the effects of organic acids and hydrogen peroxide, no inhibition of other gram-positive or -negative genera was demonstrated by L. acidophilus. The agent produced by L. acidophilus N2 and responsible for inhibition of L. leichmannii, L. bulgaricus, L. helveticus, and L. lactis was investigated. Ultrafiltration studies indicated a molecular weight of approximately 100,000 for the crude inhibitor. The agent was sensitive to proteolytic enzymes and retained full activity after 60 min at 100 degrees C (pH 5). Activity against sensitive cells was bactericidal but not bacteriolytic. These characteristics identified the inhibitory agent as a bacteriocin, designated lactacin B. Examination of strains of L. acidophilus within the six homology groupings of Johnson et al. (Int. J. Syst. Bacteriol. 30:53-68, 1980) demonstrated that production of the bacteriocin lactacin B could not be used in classification of neotype L. acidophilus strains. However, the usefulness of employing sensitivity to lactacin B in classification of dairy lactobacilli is suggested.     

Differentiation of Streptococcus lactis var. maltigenes from Other Lactic Streptococci

Strains of lactic streptococci isolated from samples of raw milk which had developed a malty aroma were subjected to the cultural, physiological, and serological tests commonly employed in the classification of streptococci. None of the strains could be differentiated from Streptococcus lactis by these tests. Resting cells of strains which produced an organoleptically detectable malty aroma when cultured in milk were usually found to possess an active α-ketoacid decarboxylase, indicating the presence of the mechanism responsible for the characteristic aroma production. This decarboxylase activity was either weak or nonexistent in the nonmalty strains, and no activity was detected in known strains of S. lactis, S. cremoris, or S. diacetilactis. The malty strains usually produced higher acidities in milk than did the nonmalty strains, and, in most instances, they developed a granular type of growth sediment in broth, as opposed to a viscid sediment. Many of them gave weakly positive Voges-Proskauer tests in glucose broth with or without added citrate and appeared to be somewhat more resistant to nisin than the nonmalty strains.     

Morphology of the Bacteriophages of Lactic Streptococci

Electron microscope studies have been made of a number of phages of lactic streptococci, seven of which were phages of Streptococcus lactis C10. Two of the phages are thought to be identical; five have been classified by the method of Tikhonenko as belonging to group IV (phages with noncontractile tails) with type III tail plates; one belongs to group V (phages with tails possessing a contractile sheath). Both prolate polyhedral heads and isometric polyhedral heads are represented among the group IV phages. The phage drc3 of S. diacetilactis DRC3 has been shown to have similar structure to the group IV phages of S. lactis C10 with prolate polyhedral heads. The phages ml1, hp, c11, and z8 of the S. cremoris strains ML1, HP, C11, and Z8, respectively, were shown to belong to the group IV phages with type III tail plates by the method of Tikhonenko. All had octahedral heads and tended to be larger than most of the other phages studied.     

Mechanisms of lactose utilization by lactic acid streptococci: enzymatic and genetic analyses

The apparent instability of beta-galactosidase in toluene-treated cells or cell-free extracts of lactic streptococci is explained by the fact that these organisms do not contain the expected enzyme. Instead, various strains of Streptococcus lactis, S. cremoris, and S. diacetilactis were shown to hydrolyze o-nitrophenyl-beta-d-galactoside-6-phosphate (ONPG-6-P), indicating the presence of a different enzyme. In addition, lactose metabolism in S. lactis C(2)F was found to involve enzyme I (EI), enzyme II (EII), factor III (FIII), and a heat-stable protein (HPr) of a phosphoenolpyruvate (PEP)-dependent phosphotransferase system analogous to that of Staphylococcus aureus. Mutants of S. lactis C(2)F, defective in lactose metabolism, possessed the phenotype lac(-) gal(-). These strains were unable to accumulate (14)C-thiomethyl-beta-d-galactoside, to hydrolyze ONPG, or to utilize lactose when grown in lactose or galactose broth. In addition, these mutants contained EI and HPr, but lacked EII, FIII, and the ability to hydrolyze ONPG-6-P. This suggested that the defect was in the phosphorylation step. Lactose-negative mutants of S. lactis 7962, a strain containing beta-galactosidase, could be separated into several classes, which indicated that this organism is not dependent upon the PEP-phosphotransferase system for lactose metabolism.     

Evaluation of Streptococcus cremoris for preparing frozen concentrated starter cultures.

Five strains of Streptococcus cremoris were investigated with respect to their usefulness for frozen concentrated biomass production. APLC medium assured high growth of 3 strains and highest cell concentration i.e. 4--6.7 g of fresh biomass from 1 litre of this medium. Two strains were sensitive to citrate present in APLC medium requiring a lowering of its dose to 0.5% in order to assure the highest biomass accumulation. The viability, endocellular proteolytic activity against casein and acidifying ability of frozen concentrates revealed that the physiological features of cells were preserved and remained unchanged during 2 and 12 weeks of storage at -30 degrees.     

Effect of heat treatment on the proteolytic activity of mesophilic bacteria isolated from goats' milk cheese

Strains of mesophilic lactococci and lactobacilli isolated from goats' milk cheese were grown to maximum density in milk at 30°C, pH 6·5. They were subsequently cooled to 12°C and then heated at 50°, 52° and 54°C (holding time, 15 s). The micro-organisms tested were Lactococcus lactis subsp. lactis IFPL 60, IFPL 22 and IFPL 359, Lactobacillus casei subsp. casei IFPL 731 and Lactobacillus plantarum IFPL 3, isolated from raw goats' milk cheese. The heated cells presented lower viability and acidification capacity than unheated cells. After heat treatment at 50°C, all the test strains effected practically no reduction in pH of milk (6 h), except for Lactococcus lactis subsp. lactis IFPL 60, which reduced pH to 5·9 as compared to 4·9 attained by the unheated controls. After treatment, proteolytic, aminopeptidase and dipeptidase activities of cell-free extracts decreased to a lesser extent than the number of viable cells with acidifying ability. The results suggest that these strains, if treated at 50°C, may be suitable as extra sources of important ripening enzymes in cheese making.