CRISPR analysis of bacteriophage-insensitive mutants (BIMs) of industrial Streptococcus thermophilus--implications for starter design.

AIMS: An efficient approach for generation of bacteriophage-insensitive mutants (BIMs) of Streptococcus thermophilus starters was described in our laboratory [Mills et al. (2007) J Microbiol Methods70, 159-164]. The aim of this study was to analyse the phage resistance mechanism responsible for BIM formation. METHODS AND RESULTS: Three clustered regularly interspaced short palindromic repeat (CRISPR) regions have been identified in Strep. thermophilus, and Strep. thermophilus can integrate novel spacers into these loci in response to phage attack. Characterization of three sets of BIMs indicated that two sets had altered CRISPR1 and/or CRISPR3 loci. A range of BIMs of yoghurt starter CSK938 were generated with the same phage in different phage challenge experiments, and each acquired unique spacer regions ranging between one and four new spacers in CRISPR1. In addition, the BIM that acquired only one new spacer in CRISPR1 also acquired an additional spacer in CRISPR3. A fourth BIM, generated with a different phage, had two spacers deleted from CRISPR1 but acquired two spacers in CRISPR3. Analysis of the Mozzarella starter CSK939 and its associated BIMs indicated that formation of second generation BIMs does not lead to increases in spacer number but to alterations in spacer regions. BIMs of an exopolysaccharide (EPS)-producing strain that lost the ability to produce EPS did not harbour an altered CRISPR, suggesting that phage sensitivity may be related to the EPS-producing phenotype. CONCLUSIONS: Acquisition/deletion of new spacers in CRISPR loci in response to phage attack generates distinctly individual variants. It also demonstrates that other modifications may be responsible for the phage resistance of Strep. thermophilus BIMs. SIGNIFICANCE AND IMPACT OF THE STUDY: Isolation of individual BIMs that have unique spacers towards the leader region of the CRISPR locus may be a very useful approach for rotation strategies with the same starter backbone. Upon phage infection, BIMs 'in reserve' can be slotted into the rotation scheme.

Efficient method for generation of bacteriophage insensitive mutants of Streptococcus thermophilus yoghurt and mozzarella strains.

Bacteriophage infection of Streptococcus thermophilus is becoming increasingly problematic in many industry fermentations such as yoghurt and mozzarella manufacture. This study describes the development of an efficient and rapid 3-step approach for the generation of bacteriophage insensitive mutants (BIMs) of these starter strains. The method initially involves infection of a culture in solid media at a multiplicity of infection (M.O.I.) of 10 which is then incubated in milk overnight. BIMs are then isolated following successive rounds (20-25) of growth in 10% reconstituted skimmed milk (RSM) in the presence of high phage titres. The method selects for BIMs which can grow efficiently in milk. Using this approach BIMs of two industrial strains were generated, whose starter performance was comparable to the parent starters in terms of performance in milk. Genomic fingerprinting used to validate the identity of each BIM, revealed a number of restriction fragment length polymorphisms (RFLPs) in two of the resultant BIMs. This method provides a simple and reliable method for generation of BIMs of industrial starters which does not require any specialised equipment and should be widely applicable.