Bacteriocin LS2

The aim of this study was to investigate the antimicrobial potential of Lactobacillus salivarius BGHO1, a human oral strain with probiotic characteristics and a broad inhibitory spectrum both against Gram-positive and Gram-negative pathogens. Here we present the bacteriocin LS2, an extremely pH- and heat-stable peptide with antilisterial activity. LS2 is a novel member of the class IId bacteriocins, unique among all currently characterised bacteriocins. It is somewhat similar to putative bacteriocins from several oral streptococci, including the cariogenic Streptococcus mutans. LS2 is a 41-amino-acid, highly hydrophobic cationic peptide of 4115.1Da that is sensitive to proteolytic enzymes. LS2 was purified from cells of strain BGHO1 by solvent extraction and reverse-phase chromatography. Mass spectrometry was used to determine the molecular mass of the purified peptide. N-terminal amino acid sequencing enabled identification of the LS2 structural gene bacls2 by a reverse genetics approach. Downstream of the bacls2 gene, two bacteriocin-like genes were found, named blp1a and blp1b, and one putative bacteriocin immunity gene named bimlp. We also present the identification of the 242-kb megaplasmid pMPHO1 by pulsed-field gel electrophoresis, which harbours the genes bacls2, blp1a, blp1b and bimlp. Two peptides with antimicrobial activity, whose approximate sizes corresponded to those of blp1a and blp1b, were identified only after culturing strain BGHO1 in a chemically defined medium. This study demonstrated the capacity of Lactobacillus salivarius BGHO1 to produce multiple bacteriocins and further established this strain as a promising probiotic candidate.

Objectives: To establish an experimental platform in Staphylococcus aureus for identifying genetic loci that determine intrinsic antibiotic susceptibility and/or that have the potential to contribute to acquired antibiotic resistance. A near-saturation S. aureus transposon (Tn) library was screened for mutants exhibiting altered susceptibility to the antistaphylococcal agents daptomycin, vancomycin and nisin. Methods: S. aureus SH1000 was mutagenized with Tn InsTet(G+)2(Cm) by electroporation of transposomes. Approximately 20500 transposants were screened for increased or reduced susceptibility to the three antistaphylococcal agents and Tn insertion sites were mapped by DNA sequencing in mutants of interest. Results: Transposants exhibiting hypersusceptibility or reduced susceptibility were identified for all three antibacterial agents; mapping of Tn insertion sites in these mutants identified genetic determinants of intrinsic susceptibility and potential contributors to acquired resistance, respectively. Tn insertions in the dlt operon caused cross-hypersusceptibility to vancomycin, daptomycin and nisin. Daptomycin hypersusceptibility was also associated with disruption of genes directing lipoteichoic acid and riboflavin biosynthesis, apparent inactivation of a putative membrane protein encoded by SAOUHSC_00957 and truncation of the cell-division gene ezrA. Tn-mediated disruption of the vraDE- and SAOUHSC_02953/4-encoded ABC transporters conferred hypersusceptibility to nisin. Reduced susceptibility to both daptomycin and vancomycin was associated with Tn insertions in rpsU and upstream of yycFG. Several loci were associated with reduced susceptibility to nisin, including two genes encoding putative glycosyltransferases. Conclusions: Tn library screening identified both known and novel modulators of antibacterial susceptibility in S. aureus and therefore represents a useful approach towards delineating the staphylococcal resistome.

Cloning natural product biosynthetic gene clusters from cultured or uncultured sources and their subsequent expression by genetically tractable heterologous hosts is an essential strategy for the elucidation and characterisation of novel microbial natural products. The availability of suitable expression hosts is a critical aspect of this workflow. In this work, we mutagenised five endogenous biosynthetic gene clusters from Streptomyces albus S4, which reduced the complexity of chemical extracts generated from the strain and eliminated antifungal and antibacterial bioactivity. We showed that the resulting quintuple mutant can express foreign biosynthetic gene clusters by heterologously producing actinorhodin, cinnamycin and prunustatin. We envisage that our strain will be a useful addition to the growing suite of heterologous expression hosts available for exploring microbial secondary metabolism.