Selection of Protease-Positive and Protease-Negative Variants of Streptococcus cremoris

Protease-negative variants were shown to outcompete the wild-type strains of Streptococcus cremoris E₈, HP, and Wg₂ at pH values higher than 6.0 in milk. For S. cremoris E₈ this process was studied in more detail. At lower pH values the wild type had a selective advantage. This pH-dependent selection was not found in all media tested. The poor growth of the protease-negative variant at low pH was not due to lower internal pH values. By growing S. cremoris E₈ and Wg₂ in acidified milk (pH 5.9) the proteolytic activity of the cultures could be stabilized. In continuous cultures under amino acid limitation the wild type S. cremoris E₈ and HP strains had a selective advantage over the protease-negative variants at low dilution rates (D < 0.2) at all pH values of the medium. This was apparently due to a lower affinity-constant (K_s) of the protease-positive variants for amino acids. Finally, a high fraction of protease-positive variants could be maintained in continuous cultures by using a growth medium with low concentrations of casein as a nitrogen source. At high dilution rates nearly all cells were protease positive.     

Properties of the Cell Walls of Lactococcus lactis subsp. cremoris SK110 and SK112 and Their Relation to Bacteriophage Resistance

Resistance of Lactococcus lactis subsp. cremoris SK110 to bacteriophage sk11G, encoded on the plasmid pSK112, is due to poor phage adsorption. Its phage-sensitive variant SK112, cured of pSK112, adsorbs phages effectively. Incubation of SK112 with concanavalin A remarkably reduced phage adsorption to this strain. This treatment also caused agglutination of SK112 that was not found with SK110, indicating different concanavalin A adsorption characteristics of cell walls of both strains. The differences between the two strains were reduced by a mild alkali treatment of cells. This resulted in a positive agglutination with concanavalin A for both strains and in parallel adsorption of phage sk11G to both. Moreover, isolated cell walls of the two strains were investigated, and both bound phage sk11G. These observations suggest the presence of phage receptor material in SK112 as well as in SK110. SK110 contained a relatively high level of bound galactose when compared with the phage-sensitive SK112. After the mild alkali treatment, however, the galactose content of SK110 was diminished such that it became comparable with that of SK112. It is hypothesized that the alkali treatment liberates a galactose-containing component from the cell wall and causes phage sensitivity in L. lactis subsp. cremoris SK110.     

Glutathione Protects Lactococcus lactis against Acid Stress

Previously we showed that glutathione (GSH) can protect Lactococcus lactis against oxidative stress (Y. Li et al., Appl. Environ. Microbiol. 69:5739-5745, 2003). In the present study, we show that the GSH imported by L. lactis subsp. cremoris SK11 or produced by engineered L. lactis subsp. cremoris NZ9000 can protect both strains against a long-term mild acid challenge (pH 4.0) and a short-term severe acid challenge (pH 2.5). This shows for the first time that GSH can protect a gram-positive bacterium against acid stress. During acid challenge, strain SK11 containing imported GSH and strain NZ9000 containing self-produced GSH exhibited significantly higher intracellular pHs than the control. Furthermore, strain SK11 containing imported GSH had a significantly higher activity of glyceraldehyde-3-phosphate dehydrogenase than the control. These results suggest that the acid stress resistance of starter culture can be improved by selecting L. lactis strains capable of producing or importing GSH.     

Glutathione Protects Lactococcus lactis against Oxidative Stress

Glutathione was found in several dairy Lactococcus lactis strains grown in M17 medium. None of these strains was able to synthesize glutathione. In chemically defined medium, L. lactis subsp. cremoris strain SK11 was able to accumulate up to ~60 mM glutathione when this compound was added to the medium. Stationary-phase cells of strain SK11 grown in chemically defined medium supplemented with glutathione showed significantly increased resistance (up to fivefold increased resistance) to treatment with H₂O₂ compared to the resistance of cells without intracellular glutathione. The resistance to H₂O₂ treatment was found to be dependent on the accumulation of glutathione in 16 strains of L. lactis tested. We propose that by taking up glutathione, L. lactis might activate a glutathione-glutathione peroxidase-glutathione reductase system in stationary-phase cells, which catalyzes the reduction of H₂O₂. Glutathione reductase, which reduces oxidized glutathione, was detectable in most strains of L. lactis, but the activities of different strains were very variable. In general, the glutathione reductase activities of L. lactis subsp. lactis are higher than those of L. lactis subsp. cremoris, and the activities were much higher when strains were grown aerobically. In addition, glutathione peroxidase is detectable in strain SK11, and the level was fivefold greater when the organism was grown aerobically than when the organism was grown anaerobically. Therefore, the presence of glutathione in L. lactis could result in greater stability under storage conditions and quicker growth upon inoculation, two important attributes of successful starter cultures.     

Associative growth studies in three-strain mixtures of lactic streptococci

A recently developed differential agar medium was used to study associative growth patterns in 17 different heterologous, three-strain mixtures of Streptococcus lactis, S. cremoris, and S. diacetilactis grown in milk. Mixtures were made by combining equal volumes of 18-hr milk cultures of the three species. Relative populations of component species were followed through three successive transfers in milk after the initial mixed propagation. Direct evidence for strain dominance and compatibility was obtained. A procedure also was developed to estimate the extent of suppression of S. lactis and S. diacetilactis in a mixture containing a dominant S. cremoris strain. The technique described could be successfully applied in quality-control work in the dairy-starter manufacturing industry.     

Effect of Fermentation Conditions on Growth of Streptococcus cremoris AM2 and Leuconostoc lactis CNRZ 1091 in Pure and Mixed Cultures

Two strains of mesophilic lactic acid bacteria, Streptococcus cremoris AM2 and Leuconostoc lactis CNRZ 1091, were grown in pure and mixed cultures in the presence or absence of citrate (15 mM) and at controlled (pH 6.5) or uncontrolled pH. Microbial cell densities at the end of growth, maximum growth rates, the pH decrease of the medium resulting from growth, and the corresponding acidification rates were determined to establish comparisons. The control of pH in pure cultures had no effect on L. lactis CNRZ 1091 populations. The final populations of S. cremoris AM2, however, were at least five times higher than when the pH was not controlled (4 × 10⁸ vs. 2 × 10⁹ CFU · ml⁻¹). The pH had no effect on the growth rate of either strain. That of S. cremoris AM2 (0.8 h⁻¹) was about twice that of L. lactis CNRZ 1091. When the pH fell below 5, the growth of both strains decreased or stopped altogether. Citrate had no effect on S. cremoris AM2, while final populations of L. lactis CNRZ 1091 were two to three times higher (3 × 10⁸ CFU · ml⁻¹); it had no effect on the maximum growth rates of the two strains. Citrate attenuated the pH decrease of the medium and reduced the maximum acidification rate of the culture by 50%, due to the growth of S. cremoris AM2. Acidification due to L. lactis CNRZ 1091, however, was very slight. Regardless of the conditions of pH and citrate, the total bacterial population in mixed culture was lower (by 39%) than that of the sum of each pure culture. Mixed culture improved the maximum growth rate of L. lactis CNRZ 1091 (0.6 h⁻¹) by 50%, while that of S. cremoris AM2 was unaffected. The acidification rate of the growth medium in mixed culture, affected by the presence of citrate, resulted from the development and activity of S. cremoris AM2.     

Conjugal Transfer of Bacteriophage Resistance Determinants on pTR2030 into Streptococcus cremoris Strains

Agar surface conjugal matings were used to introduce heat-sensitive phage resistance (Hsp⁺) determinants carried on the conjugal plasmid pTR2030 into Streptococcus cremoris KH, HP, 924, and TDM1. Lactose-fermenting (Lac⁺) transconjugants were selected from matings of Lac⁻ variants of S. cremoris KH, HP, 924, and TDM1 with Streptococcus lactis ME2 or a high-frequency donor, S. lactis T-EK1 (pTR1040, Lac⁺; pTR2030, Hsp⁺). For all of the S. cremoris strains examined, select Lac⁺ transconjugants were completely resistant to plaquing by their homologous lytic phages. In all cases the plaquing efficiencies were less than 10⁻⁹. Acquisition of a 30-megadalton plasmid (pTR2030) in the S. cremoris phage-resistant transconjugants was demonstrated by direct plasmid analysis, by hybridization with ³²P-labeled probes, or by conjugal transfer of pTR2030 out of the phage-resistant transconjugants into a plasmid-cured recipient, S. lactis LM2302. Acid production, coagulation ability, and proteolytic activity of phage-resistant transconjugants in milk were comparable to those of their phage-sensitive parents. Further, S. cremoris phage-resistant transconjugants were not attacked by phage in starter culture activity tests, which included a 40°C incubation period. The results demonstrated that phage resistance determinants on pTR2030 could be conjugally transferred to a variety of S. cremoris strains and confer resistance to phage under conditions encountered during cheese manufacture. Phage-resistant transconjugants of S. cremoris M43 and HP were also constructed without the use of antiblotic markers to select conjugal recipients from mating mixtures.     

Polyclonal Antisera To Distinguish Strains and Form Variants of Photorhabdus (Xenorhabdus) luminescens

In this study antisera against Photorhabdus luminescens strains were prepared for the first time. P. luminescens is a bacterial symbiont of entomopathogenic nematodes belonging to the genus Heterorhabditis. To characterize P. luminescens strains and form variants, we produced polyclonal antisera against P. luminescens PE (obtained from nematode strain NLH-E87.3) and against the primary and secondary forms of P. luminescens PSH (obtained from nematode strain DH-SH1). In double-diffusion tests all form variants of strain PE reacted with the antiserum against the primary form, but each variant produced a different diffusion pattern. The primary and secondary forms of strain PSH were also serologically different. Antiserum 9226 reacted with almost all P. luminescens strains tested, but it reacted differently with each strain in the double-diffusion test, showing that the strains were serologically different. The specificity of the antisera was increased by cross-absorption. After cross-absorption the antiserum against the strain PSH primary or secondary form was specific for that form and did not react with the other form. Using the cross-absorbed antisera in immunofluorescence cell-staining tests, we could distinguish primary and secondary form cells in a mixed strain PSH culture.     

A study on the possible utilization of immunodiffusion and immunofluorescence techniques as the diagnostic methods for American foulbrood of honeybees (Apis mellifera)

Four types of antisera were obtained from rabbits hyperimmunized with either spores or vegetative rods from two strains of the American foulbrood pathogen, Bacillus larvae. The specificity and sensitivity of these antisera were tested with immunofluorescence and immunodiffusion methods. No cross-reactions were observed between the antisera and other different species of Bacillus or different genera of bacteria. The specificity was not found between the antisera and two strains of B. larvae although stronger fluorescent intensity was observed between the antiserum and its corresponding strain of antigen in the immunofluorescence tests. Eight samples of 1- to 2-day-old larvae, 3- to 4-day-old larvae, decayed tissue, and dry remain, collected from eight infected colonies, were tested against antisera by the immunofluorescence and the immunodiffusion methods. The results indicated that both methods are sensitive and specific for making diagnosis of field samples of American foulbrood of honey bees.     

Studies on the effects of low temperatures on lactic acid bacteria

Studies were conducted on different strains of L. bulgaricus, L. casei, S. thermophilus, S. lactis, and S. cremoris isolated in Bulgaria and applied as pure cultures and in combinations as starters. All the strains under investigation were found to preserve, on “freezing-thawing” their characteristic morphological and biochemical properties, regardless of the temperature and rate of cooling, but the optimum freezing temperature of the strains studied is ?196 °C (in liquid nitrogen). High cooling rates provide higher viability and activity of lactic acid bacterial cells. Lactic acid streptococci, S. lactis and S. thermophilus, are considerably more resistant than lactic acid rods, L. casei and L. bulgaricus, at all the freezing regimens tested.     

Deoxyribonucleic Acid Homology Among Lactic Streptococci

A comparison was made by deoxyribonucleic acid homology of 45 strains of lactic streptococci, using two strains of Streptococcus cremoris and three strains of Streptococcus lactis as reference strains. All S. cremoris strains were grouped together by deoxyribonucleic acid homology. S. lactis strains formed a second group, except that three strains of S. lactis showed a high degree of homology with S. cremoris strains. The three Streptococcus diacetylactis strains could not be differentiated from S. lactis strains. In spite of these differences between S. lactis and S. cremoris strains, the majority of S. cremoris, S. lactis, and S. diacetylactis strains studied had at least 50% of their base sequences in common. In contrast, Streptococcus thermophilus strains generally showed little relationship with the other strains of lactic streptococci. The relevance of these findings to the selection of starter strains for cheese making is discussed.     

Potential of Lactic Streptococci to Produce Bacteriocin

A survey was made on the bacteriocin-producing potential of lactic streptococci. Bacteriocin-like activities were isolated and partially purified from about 5% of the 280 strains investigated. The frequency of production varied from about 1% in Streptococcus lactis subsp. diacetylactis to 9 and 7.5% in S. lactis and Streptococcus cremoris, respectively. Eight strains of S. cremoris produced bacteriocins which, on the basis of heat stability at different pH values and inhibitory spectrum, could be divided into four types. From 54 S. lactis strains, 5 strains produced inhibitory substances, namely, three nisin-like antibiotics and two different bacteriocins. Only 1 of 93 S. lactis subsp. diacetylactis strains produced a bacteriocin which was very similar to bacteriocins of type I in S. cremoris. All of the bacteriocins that were partially purified by ammonium sulfate precipitation showed very limited inhibitory spectra. Most of the lactic streptococci and a few members of the genera Clostridium, Leuconostoc, and Pediococcus were inhibited. None of the bacteriocins acted on gram-negative bacteria. The bacteriocinogenic strains were also characterized on the basis of plasmid content. All strains possessed between one and nine plasmids ranging from 1 to 50 megadaltons.     

Cell Surface Characteristics of Bacteriophage-Resistant Lactococcus lactis subsp. cremoris SK110 and Its Bacteriophage-Sensitive Variant SK112

Several cell surface characteristics of bacteriophage-resistant Lactococcus lactis subsp. cremoris SK110 were compared with those of its phage-sensitive derivative SK112. After centrifugation, SK110 cells resisted suspension more strongly than SK112 cells. SK112 was more negatively charged and had a more hydrophobic cell surface than SK110. Furthermore, SK112 was agglutinated in the presence of concanavalin A, whereas SK110 was not. The opposite was observed upon incubation of cells of either strain with a lectin from Ricinus communis. A mild alkali treatment decreased the differences in the cell surface characteristics of the two strains remarkably.     

Preparation of concentrated lactic streptococcus starters

Single-strain cultures of Streptococcus cremoris were grown in a semisynthetic medium with automatic pH control. After centrifugation, the cells were resuspended in sterile nonfat milk (2% of the original volume). There was no significant difference in the maximum population attained when cultures were grown at pH values of 5.5, 6.0, or 6.5 with sodium hydroxide as the neutralizer. With ammonium hydroxide as the neutralizer, maximum populations obtained were increased about twofold. In most cases, the acid-producing ability of the culture concentrates was comparable to that of fresh-milk cultures. There was some variation among strains of S. cremoris with respect to the effects of different neutralizers and levels of pH control on the biological activity of the culture concentrates. The culture concentrates were stored in liquid nitrogen for as long as 231 days without significant loss in biological activity.     

Aberrant Forms of Streptococcus cremoris HP

The cheese starter strain, Streptococcus cremoris HP, produced variant colonies when streaked on the surface of solid media and incubated at 30 or 37°C or in the presence of penicillin. Serial plating and incubation at 37°C or in the presence of penicillin resulted in the production of variants. Subculture followed by incubation at 25°C or in the absence of penicillin resulted in the reversion or partial reversion to the parent form. Colony morphology and cell morphology exhibited the characteristics of the L-phase. Evidence suggested that the aberrant forms of S. cremoris at 30°C were transitional phase variants but at 37°C and in the presence of penicillin they were L-phase variants. Electron micrographs showed that the cell walls of the variant cells were defective and that there were differences in the density and the organization of the cytoplasmic constituents compared with the parent cell.     

Quantification by real-time PCR of Lactococcus lactis subsp. cremoris in milk fermented by a mixed culture

During cheese making, interactions between different strains of lactic acid bacteria play an important role. However, few methods are available to specifically determine each bacterial population in mixed cultures, in particular for strains of the same species. The aim of this study was to develop a real-time PCR quantification method to monitor the population of Lactococcus cremoris ATCC 19257 in mixed culture with Lactobacillus rhamnosus RW-9595M and the bacteriocin-producing microorganism Lc. diacetylactis UL719. The specificity of the two primers 68FCa33 and 16SR308 used to amplify a 240-bp fragment of DNA from Lc. cremoris was demonstrated by conventional PCR. Using these primers for real-time PCR, the detection limit was 2 cfu/reaction or 200 cfu of Lc. cremoris ATCC 19257 per millilitre of mixed culture in milk. In pure culture batch fermentation, good correlation was obtained between real-time PCR and the conventional plating method for monitoring Lc. cremoris growth. In mixed culture batch fermentation, Lb. rhamnosus and Lc. cremoris decreased due to nisin Z production by Lc. diacetylactis. The decrease of the Lc. cremoris cell population detected by real-time PCR was not possible to observe by the plate count method in the presence of a Lc. diacetylactis population that was 1 log higher.An erratum to this article can be found at     

Frequencies of Bacteriophage-Resistant and Slow Acid-Producing Variants of Streptococcus cremoris

The frequencies of bacteriophage-resistant and slow acid-producing variants in 10 purified strains of Streptococcus cremoris were studied. There were considerable differences among the strains in the occurrence of both slow acid-producing and phage-resistant mutants. Nevertheless, the spontaneous rates of mutation to slow acid production were three to five orders of magnitude greater than the corresponding rates of mutation to phage resistance, suggesting that slow acid production and phage resistance are not genetically linked, although they appear in cultures concomitantly. The frequencies of slow acid-producing variants among resistant and sensitive isolates from the same parent culture were similar and appeared to be strain dependent. All phage-resistant mutants tested were found to be deficient in adsorption of the homologous bacteriophage.     

Construction of Streptococcus lactis subsp. lactis Strains with a Single Plasmid Associated with Mucoid Phenotype

Lactose-fermenting mucoid (Lac⁺ Muc⁺) variants of plasmid-free Streptococcus lactis subsp. lactis MG1614 were obtained by protoplast transformation with total plasmid DNA from Muc⁺S. lactis subsp. cremoris ARH87. By using plasmid DNA from these variants for further transformations followed by novobiocininduced plasmid curing, Lac⁻ Muc⁺ MG1614 strains containing only a single 30-megadalton plasmid could be constructed. This plasmid, designated pVS5, appeared to be associated with the Muc⁺ phenotype.     

Complementary Methodologies To Identify Specific Agrobacterium Strains

Serological techniques and restriction enzyme cleavage patterns of total DNA were used to differentiate strains of Agrobacterium spp. Forty-five wild-type and plasmid-cured Agrobacterium strains were tested by immunodiffusion and immunofluorescence against polyclonal antisera to a crude ribosome preparation from Agrobacterium strains K84, U11, B6, A323, NT1, and C58. In immunodiffusion gels, these antisera reacted only with water-phenol extracts of the homologous strain, producing a single, strain-specific precipitin line. In contrast, when the same antisera were used in immunofluorescence staining, cross-reactions occurred with a limited number of heterologous Agrobacterium strains. However, the cross-reacting heterologous cells fluoresced generally less brightly than the homologous cells. When the EcoRI-digested DNA profiles from the same Agrobacterium strains were compared, 34 distinct cleavage patterns were observed. The DNA profiles were the same for all strains sharing a common chromosomal background and correlated with the strain-specific serological reaction. The presence or absence of plasmid DNA did not alter the strain-specific serological reaction or the DNA cleavage patterns. Both the serological reaction and the restriction enzyme digestion of total DNA were complementary to each other. These methods were used successfully to identify A. radiobacter K84 strains which were recovered 6 months after being inoculated to young trees in the field.