To understand the role of cell membrane phospholipids during resistance development to cationic antimicrobial peptides (CAMPs) in Enterococcus faecalis, gradual dose-dependent single exposure pediocin-resistant (Pedr) mutants of E. faecalis (Efv2.1, Efv3.1, Efv3.2, Efv4.1, Efv4.2, Efv5.1, Efv5.2 and Efv5.3), conferring simultaneous resistance to other CAMPs, selected in previous study were characterized for cell membrane phospholipid head-groups and fatty acid composition. The involvement of phospholipids in resistance acquisition was confirmed by in vitro colorimetric assay using PDA (polydiacetylene)-biomimetic membranes. Estimation of ratio of amino-containing phospholipids to amino-lacking phospholipids suggests that phospholipids in cell membrane of Pedr mutants loose anionic character. At moderate level of resistance, the cell-membrane becomes neutralized while at further higher level of resistance, the cell-surface acquired positive charge. Increased expression of mprF gene (responsible for lysinylation of phospholipids) was also observed on acquiring resistance to pediocin in PedrE. faecalis. Decreased level of branched chain fatty acids in Pedr mutants might have contributed in enhancing rigidification of cell membrane and contributing towards resistance. The interaction of pediocin with PDA-biomimetic membranes prepared from wild-type and Pedr mutants was monitored by measuring percent colorimetric response (%CR). Increased %CR of pediocin against PDA-biomimetic membranes prepared from Pedr mutants confirmed that cell membrane phospholipids are involved in the interactions of pore formation by CAMPs. There was a direct linear relationship between percent colorimetric response and IC50 of CAMPs for wild-type and Pedr mutants. This relationship further reveals that in vitro colorimetric assay can be used effectively for quantification of resistance to CAMPs.
Bacteriocins from lactic acid bacteria (LAB) are a diverse group of antimicrobial proteins/peptides, offering potential as biopreservatives, and exhibit a broad spectrum of antimicrobial activity at low concentrations along with thermal as well as pH stability in foods. High bacteriocin production usually occurs in complex media. However, such media are expensive for an economical production process. For effective use of bacteriocins as food biopreservatives, there is a need to have heat-stable wide spectrum bacteriocins produced with high-specific activity in food-grade medium. The main hurdles concerning the application of bacteriocins as food biopreservatives is their low yield in food-grade medium and time-consuming, expensive purification processes, which are suitable at laboratory scale but not at industrial scale. So, the present review focuses on the bacteriocins production using complex and food-grade media, which mainly emphasizes on the bacteriocin producer strains, media used, different production systems used and effect of different fermentation conditions on the bacteriocin production. In addition, this review emphasizes the purification processes designed for efficient recovery of bacteriocins at small and large scale.
Staphylococcus aureus is found in a wide variety of habitats, including human skin, where many strains are commensals that may be clinically significant or contaminants of food. To determine the physiological characteristics of resistant strain of Staphylococcus aureus against pediocin, a class IIa bacteriocin, a resistant strain was compared with wild type in order to investigate the contribution of hydrophobicity to this resistance. Additional clumping of resistant strain relative to wild type in light microscopy was considered as an elementary evidence of resistance attainment. A delay in log phase attainment was observed in resistant strain compared to the wild type strain. A significant increase in cell surface hydrophobicity was detected for resistant strain in both hexadecane and xylene indicating the contribution of cell surface hydrophobicity as adaptive reaction against antimicrobial agents.
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