ISL1: a new transposable element in Lactobacillus casei

Summary The genome structures of a temperate Lactobacillus phage, FSW, and its virulent mutants, FSVs, were examined by restriction, heteroduplex and nucleotide-sequence analyses. The results showed that two out of three FSVs had the same 1.3 kbp insertion (designated as ISL1) at different positions in the FSW sequence. ISL1 was 1,256 bp long and contained at least two long open reading frames of 279 and 822 bases on one strand. Inverted repeats were found at the termini of the ISL1 which was bracketed by 3 bp direct repeats of the FSW sequence. From this evidence, we concluded that ISL1 was a transposable element in Lactobacillus casei.     

ISL2, a new mobile genetic element in Lactobacillus helveticus

Spontaneous, phenotypically stable mutations at the -galactosidase locus (lacL-lacM) in Lactobacillus helveticus were identified and analyzed. We found that a significant number of mutations were caused by integration of a new IS element, ISL2, into these lac genes. ISL2 is 858 by long, flanked by 16-bp perfect inverted repeats and generates 3-bp target duplications upon insertion. It contains one open reading frame, which shows significant homology (40.1 % identity) to the putative transposase of IS702 from Cyanobacterium calothrix. ISL2 is present in 4–21 copies in the L. helveticus genome, but it is not found in other lactic acid bacteria. Its divergence in copy number and genomic locations in different L. helveticus strains makes it useful as a tool for strain identification by genetic fingerprinting.     

Nucleotide sequence of IS26, a new prokaryotic mobile genetic element.

The DNA sequence of a new IS element, the IS26, is 820 bp long and carries 14 bp perfect terminal inverted repeats. Upon integration, IS26 generates an 8 bp duplication of its target sequence. A large open reading frame within IS26 could code for a protein of 234 amino acids. On its reverse strand, IS26 also carries one large open reading frame, 591 bp long, which contains no stop codon within IS26.     

Evidence that Lactobacillus casei insertion element ISL1 has a narrow host range.

The 1.3-kilobase-pair insertion element ISL1, originally isolated from Lactobacillus casei S-1, was found to have an extremely restricted host range. By DNA-DNA hybrizations performed with Southern transfers by using a cloned internal fragment of ISL1 as a molecular probe, it was found that only 3 of 19 L. casei strains examined contained sequences that hybridized to the ISL1 probe. In two of these, the hybridizing sequences were found on lactose plasmids. No homologous sequences were detected in a survey of 14 other Lactobacillus strains (9 species) and 15 strains of other bacteria (8 genera, 12 species).     

l-glutamate transport in Lactobacillus helveticus

An energy source (glucose or lactose) was required for the transport of l-glutamic acid by Lactobacillus helveticus. Mg²⁺, K⁺ and Li⁺ increased its accumulation while Ca²⁺ and Na⁺ decreased it. It was inhibited by NaF, indicating that ATP may be involved in uptake. Optimum transport was at pH 7.3 and 45°C. l-Glutamic acid transport showed a high degree of stereospecificity, as neither d-glutamate nor d-aspartate were active. Proton-conducting uncouplers, like carbonyl cyanide-m-chlorophenylhydrazone, and ionophores (nigericin, monensin and gramicidin) were strongly inhibitory. These results indicate that a proton motive force may be involved in the transport of l-glutamic acid.The authors are with the Centro de Referencia para Lactobacilos, Chacabuco 145 4000 S.M. de Tucumán, Argentina and the Cátedra de Microbiologia Superior, Universidad Nacional de Tucumán, Argentina.     

A new mobile genetic element inLactobacillus delbrueckii subsp.bulgaricus

A new IS element (ISL3) was discovered inLactobacillus delbrueckii subsp.bulgaricus during the characterization of the linkage relationships between the two genes important for milk fermentation,β-galactosidase (lacZ) and the cell-wall associated protease (prtP). ISL3 is a 1494 by element, flanked by 38 by imperfect inverted repeats, and generates an 8 by target duplication upon insertion. It contains one open reading frame, encoding a potential polypeptide of 434 amino acids, which shows significant homology (34% identity) to the transposase of theLeuconostoc mesenteroides element IS1165. Molecular analysis of spontaneouslacZ mutants revealed some strains that had sustained deletions of 7 to 30 kb in size, centered on and eliminating the copy of ISL3 next tolacZ. Other deletion endpoints were identified as located immediately adjacent to ISL3. Furthermore, genetic translocations that had occurred via transposition of ISL3 were observed fortuitously in cultures screened for deletion mutants. ISL3 can be found in one to several copies in various strains ofL. delbrueckii. However, it was not present in other dairy lactic acid bacteria tested.     

Gene replacement in Lactobacillus helveticus.

An efficient method for gene replacement in Lactobacillus helveticus CNRZ32 was developed by utilizing pSA3 as an integration vector. This plasmid is stably maintained in CNRZ32 at 37 degrees C but is unstable at 45 degrees C. This method consisted of a two-step gene-targeting technique: (i) chromosomal integration of a plasmid carrying an internal deletion in the gene of interest via homologous recombination and (ii) excision of the vector and the wild-type gene via homologous recombination, resulting in gene replacement. By using this procedure, the chromosomal X-prolyl dipeptidyl aminopeptidase gene (pepXP) of CNRZ32 was successfully inactivated.     

Evidence for a Plasmid-Linked Restriction-Modification System in Lactobacillus helveticus

The presence of a restriction-modification (R/M) system against two bacteriophages, 328-B1 and hv, was demonstrated in three Lactobacillus helveticus strains, CNRZ 1094, CNRZ 1095, and CNRZ 1096. In addition, the burst size of phage 328-B1 in the three restrictive strains CNRZ 1094, CNRZ 1095, and CNRZ 1096 was reduced with respect to the values obtained in its propagating strain, CNRZ 328. Heating at 60°C did not inactivate the R/M system. Nonrestrictive variants from CNRZ 1094 were easily obtained under several culture conditions, but treatment with novobiocin at 42°C followed by storage at −20°C resulted in drastic elimination of the R⁺/M⁺ phenotype from all clones tested. Electrophoretic analysis of CNRZ 1094 nonrestrictive variants revealed the concomitant loss of a 34-kb plasmid. Four EcoRI fragments from the 34-kb plasmid were cloned in the Escherichia coli vector pACYC184. The use of one or several of these fragments as probes confirmed the plasmidic location of the genes responsible for the R/M system. These probes also showed the presence of R/M plasmids in the two other restrictive strains, CNRZ 1095 and CNRZ 1096. Lactose-fermenting ability and/or proteolytic capacity was not linked to the 34-kb plasmid.     

Characterisation of a cell-envelope proteinase from Lactobacillus helveticus

The cell-envelope proteinase from Lactobacillus helveticus CRL 1062 was detected in the cell membrane fraction. The enzyme remained associated with the cells even after treatment with lysozyme and was not released from washed cells in absence of calcium. The proteinase was maximally active at pH 6.5–7.0 and 42°C and hydrolysed - and -caseins at different rates. Activity was inhibited (98%) by 1 mM PMSF, suggesting it was a serine-type protease.     

Partial characterization of a bacteriocin produced by Lactobacillus helveticus

AIMS: To investigate the antimicrobial activity of a strain of Lactobacillus helveticus. METHODS AND RESULTS: The culture supernatant fluid Lact. helveticus G51 showed antimicrobial activity against thermophilic strains of Lactobacillus. Purification of the active compound was achieved after gel filtration and ion exchange chromatography. As revealed by SDS-PAGE, active fractions were relatively homogeneous, showing a protein with a molecular mass of 12.5 kDa. The antimicrobial compound was heat labile, inactivated by proteolytic enzymes and had a bactericidal mode of action. CONCLUSION: The antimicrobial activity expressed by Lact. helveticus G51 was correlated with the production of a bacteriocin with properties that were different to other helveticins. SIGNIFICANCE AND IMPACT OF THE STUDY: The study has provided further data on Lact. helveticus bacteriocins. The strong activity of the bacteriocin towards various thermophilic lactobacilli warrants further investigation for its potential to obtain attenuated cultures for the enhancement of the cheese-ripening process.     

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.