Crucial role for insertion sequence elements in Lactobacillus helveticus evolution as revealed by interstrain genomic comparison.

Lactobacillus helveticus is a versatile dairy bacterium found to possess heterogeneous genotypes depending on the ecosystem from which it was isolated. The recently published genome sequence showed the remarkable flexibility of its structure, demonstrated by a substantial level of insertion sequence (IS) element expansion in association with massive gene decay. To assess this diversity and examine the level of genome plasticity within the L. helveticus species, an array-based comparative genome hybridization (aCGH) experiment was designed in which 10 strains were analyzed. The aCGH experiment revealed 16 clusters of open reading frames (ORFs) flanked by IS elements. Four of these ORFs are associated with restriction/modification which may have played a role in accelerated evolution of strains in a commercially intensive ecosystem undoubtedly challenged through successive phage attack. Furthermore, analysis of the IS-flanked clusters demonstrated that the most frequently encountered ISs were also those most abundant in the genome (IS1201, ISL2, ISLhe1, ISLhe2, ISLhe65, and ISLhe63). These findings contribute to the overall viewpoint of the versatile character of IS elements and the role they may play in bacterial genome plasticity.

Exploitation of the diverse insertion sequence element content of dairy Lactobacillus helveticus starters as a rapid method to identify different strains.

The species Lactobacillus helveticus is a commonly used thermophilic starter and/or adjunct culture for Swiss and Cheddar cheese manufacture. Its use is normally associated with flavour improvement which is known to be associated with culture traits such as rapid autolysis and high proteolytic activity. The genome of the commercial strain, DPC4571, was recently sequenced and found to have an abundance of IS sequences in terms of both abundance (213 intact) and diversity (21 types). Given this unique diversity for a lactic acid bacterium, we investigated whether PCR-based IS fingerprinting could be used as a discriminatory tool to distinguish between different strains of Lb. helveticus. A set of ten primers targeting five of the most numerous groups (ISL1201, ISLhe65, ISLhe2, ISLhe15 and ISL2) of IS elements was designed. Multiplex-PCR with all primers resulted in 1-12 discreet amplicons for each strain tested. The resultant fingerprints (in the 0.5 kb-3 kb range) were found to be strain specific and reproducible. This approach thus provides a valuable method to distinguish between Lb. helveticus strains while giving some indication of the relative abundance of IS sequences in each strain.

Comparative genomics of lactic acid bacteria reveals a niche-specific gene set.

BACKGROUND: The recently sequenced genome of Lactobacillus helveticus DPC4571 revealed a dairy organism with significant homology (75% of genes are homologous) to a probiotic bacteria Lb. acidophilus NCFM. This led us to hypothesise that a group of genes could be determined which could define an organism's niche. RESULTS: Taking 11 fully sequenced lactic acid bacteria (LAB) as our target, (3 dairy LAB, 5 gut LAB and 3 multi-niche LAB), we demonstrated that the presence or absence of certain genes involved in sugar metabolism, the proteolytic system, and restriction modification enzymes were pivotal in suggesting the niche of a strain. We identified 9 niche specific genes, of which 6 are dairy specific and 3 are gut specific. The dairy specific genes identified in Lactobacillus helveticus DPC4571 were lhv_1161 and lhv_1171, encoding components of the proteolytic system, lhv_1031 lhv_1152, lhv_1978 and lhv_0028 encoding restriction endonuclease genes, while bile salt hydrolase genes lba_0892 and lba_1078, and the sugar metabolism gene lba_1689 from Lb. acidophilus NCFM were identified as gut specific genes. CONCLUSION: Comparative analysis revealed that if an organism had homologs to the dairy specific geneset, it probably came from a dairy environment, whilst if it had homologs to gut specific genes, it was highly likely to be of intestinal origin.We propose that this "barcode" of 9 genes will be a useful initial guide to researchers in the LAB field to indicate an organism's ability to occupy a specific niche.

Genome sequence of Lactobacillus helveticus, an organism distinguished by selective gene loss and insertion sequence element expansion.

Mobile genetic elements are major contributing factors to the generation of genetic diversity in prokaryotic organisms. For example, insertion sequence (IS) elements have been shown to specifically contribute to niche adaptation by promoting a variety of genetic rearrangements. The complete genome sequence of the cheese culture Lactobacillus helveticus DPC 4571 was determined and revealed significant conservation compared to three nondairy gut lactobacilli. Despite originating from significantly different environments, 65 to 75% of the genes were conserved between the commensal and dairy lactobacilli, which allowed key niche-specific gene sets to be described. However, the primary distinguishing feature was 213 IS elements in the DPC 4571 genome, 10 times more than for the other lactobacilli. Moreover, genome alignments revealed an unprecedented level of genome stability between these four Lactobacillus species, considering the number of IS elements in the L. helveticus genome. Comparative analysis also indicated that the IS elements were not the primary agents of niche adaptation for the L. helveticus genome. A clear bias toward the loss of genes reported to be important for gut colonization was observed for the cheese culture, but there was no clear evidence of IS-associated gene deletion and decay for the majority of genes lost. Furthermore, an extraordinary level of sequence diversity exists between copies of certain IS elements in the DPC 4571 genome, indicating they may represent an ancient component of the L. helveticus genome. These data suggest a special unobtrusive relationship between the DPC 4571 genome and its mobile DNA complement.