Bacteriophage Resistance Conferred on Lactic Streptococci by the Conjugative Plasmid pTR2030: Effects on Small Isometric-, Large Isometric-, and Prolate-Headed Phages

A series of reactions between phages, sensitive hosts, and transconjugants where the sensitivity of small isometric-, large isometric-, and prolate-headed phages to pTR2030-induced phage resistance was evaluated in Streptococcus lactis and Streptococcus cremoris strains. Phage-resistant transconjugants were constructed in the desired host by conjugal transfer of lactose-fermenting ability (Lac⁺, pTR1040) and phage resistance (Hsp⁺, pTR2030) from S. lactis TEK1. S. lactis and S. cremoris transconjugants harboring pTR2030 were resistant to all small isometric-headed phages examined. In contrast, prolate- and large isometric-headed phages were either not inhibited in the pTR2030 transconjugants or exhibited a reduction in plaque size without a reduction in the efficiency of plaquing. Small isometric-headed phages subject to pTR2030 induced inhibition shared no significant DNA homology with pTR2030, suggesting that phage immunity genes are not harbored on the plasmid or responsible for resistance. The general effectiveness of pTR2030 against small isometric-headed phages was highly significant since these are the phages which have been isolated most commonly from dairy fermentation plants.     

Conjugal Transfer in Lactic Streptococci of Plasmid-Encoded Insensitivity to Prolate- and Small Isometric-Headed Bacteriophages

Eight of 40 strains of Streptococcus lactis and S. lactis subsp. diacetylactis were able to conjugally transfer a degree of phage insensitivity to Streptococcus lactis LM0230. Transconjugants from one donor strain, S. lactis subsp. diacetylactis 4942, contained a 106-kilobase (kb) cointegrate plasmid, pAJ1106. The plasmid was conjugative (Tra⁺) and conferred phage insensitivity (Hsp) and lactose-fermenting ability (Lac) in S. lactis and Streptococcus cremoris transconjugants. The phage resistance mechanism was effective against prolate- and small isometric-headed phages at 30°C. In S. lactis transconjugants, the phage resistance mechanism was considerably weakened at elevated temperatures. A series of deletion plasmids was isolated from transconjugants in S. cremoris 4854. Deletion plasmids were pAJ2074 (74 kb), Lac⁺, Hsp⁺, Tra⁺; pAJ3060 (60 kb), Lac⁺, Hsp⁺; and pAJ4013 (13 kb), Lac⁺. These plasmids should facilitate mapping Hsp and tra genes, with the aim of constructing phage-insensitive strains useful to the dairy industry.     

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.     

Resistance against Industrial Bacteriophages Conferred on Lactococci by Plasmid pAJ1106 and Related Plasmids

Plasmid pAJ1106 and its deletion derivative, plasmid pAJ2074, conferred lactose-fermenting ability (Lac) and bacteriophage resistance (Hsp) at 30°C to Lac⁻ proteinase (Prt)-negative Lactococcus lactis subsp. lactis and L. lactis subsp. lactis var. diacetylactis recipient strains. An additional plasmid, pAJ331, isolated from the original source strain of pAJ1106, retained Hsp and conjugative ability without Lac. pAJ331 was conjugally transferred to two L. lactis subsp. lactis and one L. lactis subsp. cremoris starter strains. The transconjugants from such crosses acquired resistance to the phages which propagated on the parent recipient strains. Of 10 transconjugant strains carrying pAJ1106 or one of the related plasmids, 8 remained insensitive to phages through five activity test cycles in which cultures were exposed to a large number of industrial phages at incubation temperatures used in lactic casein manufacture. Three of ten strains remained phage insensitive through five cycles of a cheesemaking activity test in which cultures were exposed to approximately 80 different phages through cheesemaking temperatures. Three phages which propagated on transconjugant strains during cheesemaking activity tests were studied in detail. Two were similar (prolate) in morphology and by DNA homology to phages which were shown to be sensitive to the plasmid-encoded phage resistance mechanism. The third phage was a long-tailed, small isometric phage of a type rarely found in New Zealand cheese wheys. The phage resistance mechanism was partially inactivated in most strains at 37°C.     

Involvement of a Plasmid in Production of Ropiness (Mucoidness) in Milk Cultures by Streptococcus cremoris MS

Curing and genetic transfer experiments showed that lactose-fermenting ability (Lac⁺) and the ability to produce mucoidness in milk cultures (Muc⁺) in Streptococcus cremoris MS were coded on plasmids. The Lac⁺ phenotype was associated with a 75.8-megadalton plasmid, pSRQ2201. The Muc⁺ phenotype was associated with a 18.5-megadalton plasmid, pSRQ2202. The Lac plasmid, pSRQ2201, was first conjugatively transferred from S. cremoris MS to Lac⁻S. lactis ML-3/2.2. Later, the Muc plasmid, pSRQ2202, was conjugatively transferred from Lac⁻ Muc⁺S. cremoris MS04 to Lac⁺ nonmucoid S. lactis transconjugant ML-3/2.201. Subsequently, pSRQ2201 and pSRQ2202 were cotransferred from Lac⁺ Muc⁺S. lactis transconjugant ML-3/2.202 to Lac⁻, nonmucoid, malty S. lactis 4/4.2 and S. lactis subsp. diacetylactis SLA3.25. Transconjugants showing pSRQ2201 were Lac⁺; those containing pSRQ2202 were Muc⁺. With the transfer of pSRQ2202, the transconjugants S. lactis ML-3/2.202 and S. lactis subsp. diacetylactis SLA3.2501 not only acquired the Muc⁺ phenotype but also resistance to bacteriophages, which were lytic to the respective parent strains S. lactis ML-3/2.201 and S. lactis subsp. diacetylactis SLA3.25.     

Genetic evidence for plasmid-encoded lactococcin production inLactococcus lactis subsp.lactis 484

Lactococcus lactis subsp.lactis 484 produced a proteinaceous antibacterial substance designated as lactococcin capable of inhibiting members of theLactococcus group,Bacillus cereus, Staphylococcus aureus, andSalmonella typhi. Growth of this culture in the presence of 2–30 g/ml of ethidium bromide or acriflavin or novobiocin, and at elevated temperature (39° and 41°C), could not produce any lactococcin-negative (Lap^–) variants. However, protoplast-induced curing with lysozyme was successful in developing Lap^– derivatives. Two types of cured derivatives, namely Lac^– Lap⁺ and Lac^– Lap^–, were obtained. Lap^– variants were also lacking sucrose-fermenting ability (Suc⁺) and lactococcin resistance (Lap^r). The lactose-negative (Lac^–) variants and Lap⁺ were clearly lacking the largest (65 Md) plasmid. However, Lap^– Suc^– Lap^s variants lost a 2 Md plasmid.L. lactis subsp.lactis 484 transferred lactose-fermenting ability as well as Lap⁺ Suc⁺ Lap^r phenotypes simultaneously toL. lactis subsp.lactis LM 2306 and LM 0230 by surface mating at a frequency of 10^–4 and 10^–1 per donor respectively. However, cured Lac^– Lap^– transconjugants could not transfer Lac⁺ Lap⁺ Suc⁺ Lap^r phenotypes to any of these recipient strains. Our results indicate that Lac⁺ and Lap⁺ Suc⁺ Lap^r phenotypes are associated with 65 Md and 2 Md plasmids respectively. Conjugal transfer of 2 Md plasmid is possible only in the presence of a conjugative 65 Md plasmid.     

Conjugal transfer of lactose-fermenting ability fromStreptococcus lactis C2 toLeuconostoc cremoris CAF7 yieldsLeuconostoc that ferment lactose and produce diacetyl

Summary Conjugation between lactose-fermenting (Lac⁺)Streptococcus lactis C2 and Lac^– Leuconostoc cremoris CAF7 was performed. The frequency of Lac⁺ transfer was 1.5 · 10^–2 per donor cell. Lac⁺ Leuconostoc transconjugants could ferment lactose significantly faster than wild-type cells. When grown in litmus milk fortified with 0.2% yeast extract, Lac⁺ transconjugants reached pH 4.68 within 24 h at 30°C and produced diacetyl. The identity of the transconjugants asLeuconostoc derivatives was confirmed by their resistance to phage c2 and to vancomycin (>500 g/ml), and by growth on selective medium containing azide. Plasmid profiles of 10 transconjugants showed two unique patterns. A novel enlarged plasmid was found. Southern blot hybridization revealed some homology with the 30 Md Lac⁺ plasmid of donor, recipient and the transconjugants, as well as with some of the remaining plasmids of the donor.Technical Paper No. 7953, Oregon Agricultural Experiment Station.     

Cotransformation of lactococcin-producing, 2.0-mega dalton and erythromycin-resistant pGB 301 plasmids toLactococcus lactis subsp.lactis protoplast

Protoplasts of plasmid-freeLactococcus lactis subsp.lactis LM 0230 and PC₄ strains were cotransformed successfully with the plasmid pools ofL. lactis subsp.lactis 484, a lactosefermenting (Lac⁺), lactococcin-producing (Lap⁺), lactococcin-resistant (Lap^r), sucrosefermenting (Suc⁺) wild strain, its derivatives, and pGB 301 erythromycin resistance plasmid (Ery^r) at the frequencies of 10⁴ transformants/g of DNA. PC₄ protoplasts were transformed at slightly lower frequencies that LM 0230 protoplasts when the same plasmid combinations were used for transformation. Agarose gel electrophoresis of plasmids from three groups of transformants, namely, Lac^–Lap^–Ery^r, Lac⁺Suc⁺Lap⁺Lap^rEry^r, and Lac^–Suc⁺Lap⁺ Lap^rLap^r, confirmed that 2.0 and 65.0 megadalton (MDa) plasmids carried genes for Suc⁺Lap⁺Lap^r and Lac⁺ phenotypes respectively. The protoplasts could be transformed with low-molecular-weight 2.0 MDa Lap plasmid at a relatively higher frequency than those with high-molecular-weight 65.0 MDa Lac plasmid. All the transformants resembled parent culture 484 in terms of lactic acid production (0.810–0.840%), milk curdling time (6 h), and lactococcin activity (7–12 mm, zone of inhibition) againstListeria monocytogenes, Salmonella typhi, andStaphylococcus aureus. The plasmids and their respective phenotypes in PC₄ transformants were genetically more stable than those of LM 0230 protoplasts. The marker plasmid pGB 301 disappeared more frequently from the transformants when present in association with the lowmolecular-weight, high-copy-number 2.0 MDa plasmid, thereby suggesting the incompatibility of these two plasmids.     

Stabilization of Lactose Metabolism in Streptococcus lactis C2

The integration of the lactose plasmid from lactic streptococci into the host chromosome could stabilize this trait for dairy fermentations. Sixty lactose-positive (Lac⁺) transductants of lactose- and proteinase-negative (Lac⁻ Prt⁻) LM0220 were induced for temperature phage by UV irradiation or mitomycin C. Four of the transductants, designated KB18, KB21, KB54, and KB58, yielded lysates demonstrating less than one Lac⁺ transductant per 0.2 ml of phage lysate. Successive transferring in the presence of acriflavine did not yield Lac⁻ segregants from KB18, KB21, KB54, or KB58, whereas Streptococcus lactis C2 (parent culture) and three other Lac⁺ transductants showed 12 to 88% conversion from Lac⁺ to Lac⁻ within 6 to 10 repetitive transfers. When grown in continuous culture, KB21 did not show any Lac⁻ variants in 168 h, while S. lactis C2 had 96% conversion from Lac⁺ to Lac⁻ in 144 h. Agarose gel electrophoresis of plasmid DNA isolated from KB18, KB21, KB54, and KB58 revealed that the lactose plasmid, pLM2103, normally present in Lac⁺ transductants, was missing. This suggested integration of the transferred lactose plasmid into the chromosome. In contrast to phage lysates induced from S. lactis C2, which exhibited an exponential decrease in the number of Lac⁺ transductants after exposure to small doses of UV irradiation, the transduction frequency for lactose metabolism was stimulated by UV irradiation of lysates from KB58. The latter indicated chromosomal linkage for lac and that integration of the lactose genes plasmid into the chromosome had occurred.     

Conjugal Transfer of Genetic Information in Group N Streptococci

Streptococcus lactis strains ML3 and C₂O and S. lactis subsp. diacetylactis strains DRC3, 11007, and WM₄ were found to transfer lactose-fermenting ability to LM0230, an S. lactis C2 lactose-negative (Lac⁻) derivative which is devoid of plasmid deoxyribonucleic acid (DNA). Lactose-positive streptomycin-resistant (Lac⁺ Str^r) recombinants were found when the Lac⁺ Str^s donor was mixed with Lac⁻ Str^r LM0230 in solid-surface matings. Transduction and transformation were ruled out as the mechanism of genetic exchange in strains ML3, DRC3, 11007, and WM₄, nor was reversion responsible for the high number of Lac⁺ Str^r recombinants. Furthermore, chloroform treatment of the donor prevented the appearance of recombinants, indicating that transfer of lactose-fermenting ability required viable cell-to-cell contact. Strain C₂O demonstrated transduction as well as conjugation. Transfer of plasmid DNA during conjugation for all strains was confirmed by demonstrating the presence of plasmid DNA in the transconjugants by using agarose gel electrophoresis. In some instances, a cryptic plasmid was transferred in conjunction with the lactose plasmid by using strains DRC3, 11007, and WM₄. In S. lactis C2 × LM0230 matings, the Str^r marker was transferred from LM0230 to C2, suggesting conjugal transfer of chromosomal DNA. The results confirm conjugation as another mechanism of genetic exchange occurring in dairy starter cultures.     

Effect of X-Prolyl Dipeptidyl Aminopeptidase Deficiency on Lactococcus lactis

The genetic determinant (pepXP) of an X-prolyl dipeptidyl aminopeptidase (PepXP) has recently been cloned and sequenced from both Lactococcus lactis subsp. cremoris (B. Mayo, J. Kok, K. Venema, W. Bockelmann, M. Teuber, H. Reinke, and G. Venema, Appl. Environ. Microbiol. 57:38-44, 1991) and L. lactis subsp. lactis (M. Nardi, M.-C. Chopin, A. Chopin, M.-M. Cals, and J.-C. Gripon, Appl. Environ. Microbiol. 57:45-50, 1991). To examine the possible role of the enzyme in the breakdown of caseins required for lactococci to grow in milk, integration vectors have been constructed and used to specifically inactivate the pepXP gene. After inactivation of the gene in L. lactis subsp. lactis MG1363, which is Lac^- and Prt^-, the Lac⁺ Prt⁺ determinants were transferred by conjugation by using L. lactis subsp. lactis 712 as the donor. Since growth of the transconjugants relative to the PepXP⁺ strains was not retarded in milk, it was concluded that PepXP is not essential for growth in that medium. It was also demonstrated that the open reading frame ORF1, upstream of pepXP, was not required for PepXP activity in L. lactis. A marked difference between metenkephalin degradation patterns was observed after incubation of this pentapeptide with cell extracts obtained from wild-type lactococci and pepXP mutants. Therefore, altered expression of the pepXP-encoded general dipeptidyl aminopeptidase activity may change the peptide composition of fermented milk products.     

Effect of Increasing the Copy Number of Bacteriophage Origins of Replication, in trans, on Incoming-Phage Proliferation

Bacteriophage resistance mechanisms which are derived from a bacteriophage genome are termed Per (phage-encoded resistance). When present in trans in Lactococcus lactis NCK203, Per50, the cloned origin of replication from phage 50, interferes with 50 replication. The per50 fragment was found to afford negligible protection to NCK203 against 50 infection when present in a low-copy-number plasmid, pTRK325. A high-copy-number Per50 construct (pTRK323) dramatically affected 50 infection, reducing the efficiency of plaquing (EOP) to 2.5 × 10^-4 and the plaque size to pinhead proportions. This clone also afforded significant protection against other related small isometric phages. Per31 was cloned from phage 31 and demonstrated to function as an origin of replication by enabling replication of per31-containing plasmids, in NCK203, on 31 infection. A low-copy-number Per31 plasmid (pTRK360) reduced the EOP of 31 on NCK203 to 0.3 and the plaque diameter from 1.5 to 0.5 mm. When this plasmid was cloned in high copy number, the EOP was further reduced to 7.2 × 10^-7 but the plaques were large and contained Per31-resistant phages. Characterization of these “new” phages revealed at least two different types that were similar to 31, except that DNA alterations were noted in the region containing the origin. This novel and powerful abortive phage resistance mechanism should prove useful when directed at specific, problematic phages.     

Transfer of Sucrose-Fermenting Ability and Nisin Production Phenotype among Lactic Streptococci

Transfer of sucrose fermentation ability, nisin production, and nisin resistance from Streptococcus lactis to S. lactis and Streptococcus lactis subsp. diacetylactis occurred between cells immobilized on nitrocellulose filters in the presence of DNase. Transconjugants were able to act as donors to transfer the Suc-Nis phenotype in subsequent mating. No changes in sensitivity to lytic phage c2 were noted in S. lactis transconjugants. However, temperature-independent restriction of lytic phage 18-16 was noted in transconjugants of S. lactis subsp. diacetylactis 18-16. Adsorption studies with phage-resistant transconjugants showed that resistance was not due to lack of adsorption by the lytic phage. Physical evidence for the presence of introduced plasmid DNA was not found in lysates of transconjugants.     

Controlled Integration into the Lactococcus Chromosome of the pCI829-Encoded Abortive Infection Gene from Lactococcus lactis subsp. lactis UC811

The phage insensitivity gene of lactococcal plasmid pCI829 which encodes an abortive infection defense mechanism (Abi) was inserted into the Lactococcus lactis subsp. lactis CH919 chromosome by utilizing the integration plasmid pCI194, which contains 4.2 kb of homology with the conjugative transposon Tn919. Chloramphenicol-resistant transformants expressed phage insensitivity to the prolate-headed phage c2 and the small isometric-headed phage 712, and hybridization analysis indicated that transformants contained pCI194 integrated in single copy. The level of phage insensitivity expressed by the transformants was reduced from that observed when the abi gene was located on a replicating plasmid, as determined by plaque assay and burst size analysis. Amplification of the integrated structure after growth in increased concentrations of chloramphenicol resulted in an increase in the expression of phage insensitivity. Hybridization analysis revealed that while pCI194 was stably maintained in an integrated state over 100 generations in the absence of selective pressure, the ability to express phage insensitivity was lost. Hybridization analysis also revealed that DNA flanking the abi gene contains homology to the CH919 chromosome.     

Streptococcus cremoris M12R transconjugants carrying the conjugal plasmid pTR2030 are insensitive to attack by lytic bacteriophages.

Conjugal transfer of lactose-fermenting ability (Lac+), nisin resistance (Nisr), and phage resistance (Hsp+) was demonstrated in matings between Streptococcus lactis ME2 (donor) and Streptococcus cremoris M43a (recipient), a derivative of M12R. Transconjugants were detected by transfer of Lac+ and were found to exhibit Nisr and harbor a 40-megadalton plasmid (pTR1040). Fifty-six percent of Lac+ transconjugants were resistant to the S. cremoris M12R lytic phage. Efficiency of plaquing for phage m12r . M12 on a phage-resistant transconjugant, T2r-M43a, was less than 4.3 X 10(-10). Five additional phages which were virulent for S. cremoris M12R and isolated from industrial sources failed to plaque on S. cremoris T2r-M43a. Mating experiments with T2r-M43a revealed that phage resistance was accompanied by high-frequency conjugation ability (Tra+) and the appearance of both pTR1040 and pTR2030 encoding Lac+ Nisr and Tra+ Hsp+, respectively, in transconjugants of S. lactis LM2302. Phage-sensitive Lac+ transconjugants of S. cremoris M43a (T2s-M43a) showed no conjugal ability. These observations confirmed that pTR2030 was present and responsible for the phage resistance and conjugal ability exhibited by the S. cremoris transconjugant T2r-M43a. Unlike the S. lactis LM2302 transconjugant carrying pTR2030, resistance of T2r-M43a to phage was not affected at high temperatures (35 to 40 degrees C) or destabilized in repeated transfers through a starter culture activity test. These results demonstrated that phage resistance conferred by pTR2030 in the S. cremoris transconjugant was effective against industrially significant phages under fermentation conditions normally encountered during cheese manufacture.     

Evidence of a Restriction/Modification System in Lactobacillus delbrueckii subsp. lactis CNRZ 326

Lactobacillus delbrueckii subsp. lactis (Lb. lactis) CNRZ 326 is widely used in the propagation of Lb. delbrueckii bacteriophages. In this study, evidence is presented that this strain possesses a restriction-modification (R/M) system. The mitomycin C-induced temperate bacteriophage lb539 has a reduced efficiency of plaquing (EOP) on CNRZ 326 cells (EOP = 10⁻³), but after several passages on this strain, or on the indicator strain Lb. lactis LKT, the recovered phages (phages lb539.326 and lb539.LKT) have an EOP equal to 1. Restrictive development on CNRZ 326 was also observed after phage lb539.326 was propagated on the strain Lb. lactis CRL 934. The R/M system was also active against the virulent Lb. delbrueckii phage ll-h. Plasmid DNA was not detected in CNRZ 326, which suggests that the R/M system described is chromosomally encoded. Received: 11 September 1997 / Accepted: 21 October 1997     

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.     

Streptococcus cremoris M12R transconjugants carrying the conjugal plasmid pTR2030 are insensitive to attack by lytic bacteriophages

Conjugal transfer of lactose-fermenting ability (Lac+), nisin resistance (Nisr), and phage resistance (Hsp+) was demonstrated in matings between Streptococcus lactis ME2 (donor) and Streptococcus cremoris M43a (recipient), a derivative of M12R. Transconjugants were detected by transfer of Lac+ and were found to exhibit Nisr and harbor a 40-megadalton plasmid (pTR1040). Fifty-six percent of Lac+ transconjugants were resistant to the S. cremoris M12R lytic phage. Efficiency of plaquing for phage m12r . M12 on a phage-resistant transconjugant, T2r-M43a, was less than 4.3 X 10(-10). Five additional phages which were virulent for S. cremoris M12R and isolated from industrial sources failed to plaque on S. cremoris T2r-M43a. Mating experiments with T2r-M43a revealed that phage resistance was accompanied by high-frequency conjugation ability (Tra+) and the appearance of both pTR1040 and pTR2030 encoding Lac+ Nisr and Tra+ Hsp+, respectively, in transconjugants of S. lactis LM2302. Phage-sensitive Lac+ transconjugants of S. cremoris M43a (T2s-M43a) showed no conjugal ability. These observations confirmed that pTR2030 was present and responsible for the phage resistance and conjugal ability exhibited by the S. cremoris transconjugant T2r-M43a. Unlike the S. lactis LM2302 transconjugant carrying pTR2030, resistance of T2r-M43a to phage was not affected at high temperatures (35 to 40 degrees C) or destabilized in repeated transfers through a starter culture activity test. These results demonstrated that phage resistance conferred by pTR2030 in the S. cremoris transconjugant was effective against industrially significant phages under fermentation conditions normally encountered during cheese manufacture.     

Characterization of Phage-Sensitive Mutants from a Phage-Insensitive Strain of Streptococcus lactis: Evidence for a Plasmid Determinant that Prevents Phage Adsorption

A phage-insensitive strain of Streptococcus lactis, designated ME2, was used as a prototype strain for the study of mechanisms and genetics of phage resistance in the lactic streptococci. Mutants sensitive to a Streptococcus cremoris phage, ϕ18, were isolated at a level of 17% from cultures of ME2 after sequential transfer at 30°C. Phage-sensitive mutants of ME2 were not fully permissive to ϕ18. The efficiency of plating of ϕ18 on the mutants was 5 × 10⁻⁷ as compared with <10⁻⁹ for ϕ18 on ME2. Further characterization of the mutants showed that they efficiently adsorbed ϕ18 at levels of >99.8%, whereas ME2 adsorbed only 20 to 40% of ϕ18. These results suggest that increased phage susceptibility of the mutants may result from the loss of a mechanism that inhibits phage adsorption. Moreover, the high frequency of spontaneous mutation in ME2 indicates the involvement of an unstable genetic determinant in this phage defense mechanism. ME2 was shown to possess 13 plasmids ranging in size from 1.6 to 34 megadaltons. Of 40 mutants examined that had increased efficiencies of plating, all were missing a 30-megadalton plasmid, pME0030. These data suggest that pME0030 codes for a function that prevents phage adsorption. Further phenotypic characterization of the phage-sensitive mutants showed that some mutants were deficient in the ability to ferment lactose (Lac) and hydrolyze milk proteins (Prt). However, the Lac⁺ and Prt⁺ phenotype segregated independently of the phage-sensitivity phenotype. One phage-sensitive adsorption mutant, designated N1, was tested for susceptibility to 14 different phages. N1 showed increased capacity to adsorb 4 and to replicate 2 of these 14 phages, thereby indicating a phage resistance mechanism in ME2 that generalizes to phage interactions other than the specific ϕ18-ME2 phage-host interaction. These data provide evidence for a unique plasmid-linked phage defense mechanism in phage-insensitive strains of lactic streptococci.     

Lactococcal Bacteriophages Require a Host Cell Wall Carbohydrate and a Plasma Membrane Protein for Adsorption and Ejection of DNA

The mechanism of the initial steps of bacteriophage infection in Lactococcus lactis subsp. lactis C2 was investigated by using phages c2, ml3, kh, l, h, 5, and 13. All seven phages adsorbed to the same sites on the host cell wall that are composed, in part, of rhamnose. This was suggested by rhamnose inhibition of phage adsorption to cells, competition between phage c2 and the other phages for adsorption to cells, and rhamnose inhibition of lysis of phage-inoculated cultures. The adsorption to the cell wall was found to be reversible upon dilution of the cell wall-adsorbed phage. In a reaction step that apparently follows adsorption to the cell wall, all seven phages adsorbed to a host membrane protein named PIP. This was indicated by the inability of all seven phages to infect a strain selected for resistance to phage c2 and known to have a defective PIP protein. All seven phages were inactivated in vitro by membranes from wild-type cells but not by membranes from the PIP-defective, phage c2-resistant strain. The mechanism of membrane inactivation was an irreversible adsorption of the phage to PIP, as indicated by adsorption of [³⁵S] methionine-labeled phage c2 to purified membranes from phage-sensitive cells but not to membranes from the resistant strain, elimination of adsorption by pretreatment of the membranes with proteinase K, and lack of dissociation of ³⁵S from the membranes upon dilution. Following membrane adsorption, ejection of phage DNA occurred rapidly at 30°C but not at 4°C. These results suggest that many lactococcal phages adsorb initially to the cell wall and subsequently to host cell membrane protein PIP, which leads to ejection of the phage genome.