Lasso
peptides, a class of ribosomally synthesized and post-translationally
modified peptides (RiPPs) secreted by bacteria, have antimicrobial
activity. Here, a novel lasso peptide, microcin Y (MccY), was discovered
and characterized. The gene cluster for MccY synthesis was cloned
for expression in Escherichia coli.
This peptide was purified by HPLC and characterized by Q-TOF. MIC
assays showed that some Bacillus, Staphylococcus, Pseudomonas, Shigella, and Salmonella strains were sensitive to MccY. Interestingly,
Salmonellatyphimurium and Salmonella
infantis were efficiently inhibited by MccY, while they were
not affected by MccJ25, a lasso peptide that has antibacterial effects
on many Salmonella strains. Furthermore, MccY-resistant
strains of S. typhimurium were screened,
and mutations were found in FhuA and SbmA, indicating the importance
of these transporters for MccY absorption. This novel peptide can
greatly broaden the antimicrobial spectrum of MccJ25 in Salmonella and is expected to be used in food preservation and animal feed
additive areas.
BackgroundThe original anaerobic unsaturated fatty acid biosynthesis pathway proposed by Goldfine and Bloch was based on in vivo labeling studies in Clostridium butyricum ATCC 6015 (now C. beijerinckii) but to date no dedicated unsaturated fatty acid biosynthetic enzyme has been identified in Clostridia. C. acetobutylicium synthesizes the same species of unsaturated fatty acids as E. coli, but lacks all of the known unsaturated fatty acid synthetic genes identified in E. coli and other bacteria. A possible explanation was that two enzymes of saturated fatty acid synthesis of C. acetobutylicium, FabZ and FabF might also function in the unsaturated arm of the pathway (a FabZ homologue is known to be an unsaturated fatty acid synthetic enzyme in enterococci).ResultsWe report that the FabF homologue located within the fatty acid biosynthetic gene cluster of C. acetobutylicium functions in synthesis of both unsaturated fatty acids and saturated fatty acids. Expression of this protein in E. coli functionally replaced both the FabB and FabF proteins of the host in vivo and replaced E. coli FabB in a defined in vitro fatty acid synthesis system. In contrast the single C. acetobutylicium FabZ homologue, although able to functionally replace E. coli FabZ in vivo and in vitro, was unable to replace FabA, the key dehydratase-isomerase of E. coli unsaturated fatty acid biosynthesis in vivo and lacked isomerase activity in vitro.ConclusionThus, C. acetobutylicium introduces the double of unsaturated fatty acids by use of a novel and unknown enzyme.
Haemophilus parasuis outer membrane protein P2 (OmpP2), the most abundant protein in the outer membrane, has been identified as an antigenic protein and a potential virulence factor. To study the precise function of OmpP2, an ompP2-deficient mutant (ΔompP2) of a H. parasuis serovar 4 clinical strain SC096 was constructed by a modified natural transformation system. Compared with the wild-type SC096 strain, the ΔompP2 mutant showed a pronounced growth defect and exhibited significantly greater sensitivity to the bactericidal action of porcine and rabbit sera, whereas the complemented strain could restore the growth and serum resistance phenotypes. The results indicated that H. parasuis OmpP2 from SC096 strain is an important surface protein involved in serum resistance.
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