Characterization of closely related lactococcal starter strains which show differing patterns of bacteriophage sensitivity.

AIMS: To characterize a group of closely related Lactococcus lactis subsp. lactis casein starter strains used commercially, which differ in their sensitivity to bacteriophages isolated from the same industrial environment. METHODS AND RESULTS: Nine strains of L. lactis, six of which had been used as starter cultures for lactic casein manufacture, were shown to be closely related by pulsed-field gel electrophoresis and total DNA profiles. Nineteen phages which propagated on one or more of these starter strains were isolated from industrial casein whey samples. The phages were all small isometric-headed and could be divided into five groups on the basis of host range on the nine strains. Most of the phages did not give a PCR product with primers designed to detect the two most common lactococcal small isometric phage species (936 and P335). The hosts could be divided into six groups depending on their phage sensitivity. Plasmids encoding genes for the cell envelope associated PI-type proteinase, lactose metabolism and specificity subunits of a type I restriction/modification system were identified. CONCLUSIONS: This work demonstrates how isolates of the same starter strain may come to be regarded as separate cultures because of their different origins, and how these closely related strains may differ in some of their industrially relevant characteristics. SIGNIFICANCE AND IMPACT OF THE STUDY: This situation may be very common among lactococci used as dairy starter cultures, and implies that the dairy industry worldwide depends on a small number of different strains.

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 degrees 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 degrees C.