Giotis Efstathios S, Julotok Mudcharee, Wilkinson Brian J, Blair Ian S, McDowell David A
Food Microbiology Research Unit, University of Ulster, Northern Ireland BT37 0QB, United Kingdom.
J Food Prot. 2008 Jul;71(7):1481-5. doi: 10.4315/0362-028x-71.7.1481.
Many of the considerable abilities of Listeria monocytogenes to persist and grow in a wide range of adverse environmental conditions are thought to be at least partly under the control of the alternative sigma factor (sigmaB), encoded by the sigB gene. However, little is known about the role of this master regulon in the impressive ability of Listeria to persist and grow under conditions of alkaline pH. In this study, Northern blot analysis of parent Listeria mRNA revealed that alkali adaptation (pH 9.5 for 1 h) significantly increased the expression of sigB-derived mRNA. The study included a comparison of the relative survival of mid-exponential populations of adapted and nonadapted parent type (sigmaB expressing) and mutant (not sigmaB expressing, deltasigB) Listeria strains during subsequent alkaline (pH 12.0), osmotic (25% NaCl, wt/vol), or ethanol (16.5%) stress. Alkali-adapted parent strains were more resistant to pH 12.0 than were adapted deltasigB type strains, but both alkali-adapted parent and deltasigB strains were more resistant to pH 12.0 than were nonadapted strains. Alkali-adapted parent strains were more resistant to osmotic stress than were adapted deltasigB type strains. No significant differences in viability were observed between alkali-adapted parent and deltasigB strains after ethanol stress, suggesting that cross-protection against osmotic stress is mediated by sigmaB whereas cross-protection against ethanol is sigmaB independent. Overall, alkali-induced cross-protection against osmotic and ethanol challenges may have serious implications for food safety and human health because such stress conditions are routinely used as part of food preservation and surface cleaning processes.
人们认为,单核细胞增生李斯特菌在多种不利环境条件下持续存在并生长的诸多强大能力,至少部分受由sigB基因编码的替代σ因子(σB)控制。然而,对于这个主要调控因子在李斯特菌于碱性pH条件下令人瞩目的持续存在和生长能力中所起的作用,人们却知之甚少。在本研究中,对亲本李斯特菌mRNA进行的Northern印迹分析显示,碱适应(pH 9.5处理1小时)显著增加了源自sigB的mRNA的表达。该研究比较了适应和未适应的亲本型(表达σB)及突变型(不表达σB,ΔsigB)李斯特菌菌株的指数中期群体在随后的碱性(pH 12.0)、渗透(25% NaCl,重量/体积)或乙醇(16.5%)应激期间的相对存活率。碱适应的亲本菌株比适应的ΔsigB型菌株对pH 12.0更具抗性,但碱适应的亲本菌株和ΔsigB菌株对pH 12.0的抗性均强于未适应的菌株。碱适应的亲本菌株比适应的ΔsigB型菌株对渗透应激更具抗性。乙醇应激后,碱适应的亲本菌株和ΔsigB菌株在活力上未观察到显著差异,这表明针对渗透应激的交叉保护由σB介导,而针对乙醇的交叉保护则不依赖于σB。总体而言,碱诱导的针对渗透和乙醇挑战的交叉保护可能对食品安全和人类健康具有严重影响,因为此类应激条件通常作为食品保存和表面清洁过程的一部分被使用。
