LuxS-deficiency reduces persistence of Cronobacter to low-moisture but contributes to virulence after rehydration.

Low-moisture foods (LMF) have arisen an increasing concern as vehicles of foodborne pathogens. Cronobacter genus, a class A pathogen in powdered infant formula (PIF), is crucial to the safety of LMF. Researchers have concentrated more on the bacterial survival caused by key hazardous factors, yet they often ignore the alteration of virulence properties in the surviving strains following rehydration of LMF mediated by the key factors. Our previous transcriptional profiling showed that luxS might participate in desiccation response. Herein, we further investigated the role of Cronobacter LuxS under desiccation stress by combining with the phenotypic and gene analysis between the Cronobacter parent and luxS mutant strains. Desiccation stress destructing assays confirmed that luxS can significantly enhance the resistance of Cronobacter towards desiccation. Our results also showed that cell hydrophobicity, aggregation, motility, the content of polysaccharide, and AI-2 synthesis pathway involved in luxS-mediated desiccation response. The luxS mutant strain exhibited higher swimming and swarming motility, more content of capsular polysaccharide, and more rapid of aggregation, but lower hydrophobicity than that of the wild-type strain, whereas desiccation stress would result in a opposite effect on these cell surface properties in ΔluxS during rehydration. Additionally, the comparation of gene expression profiles indicated that low moisture would trigger Cronobacter luxS to promote transport osmoprotectants by regulating the expression of proX, proW, and treC, and suppress the expression of cpsG associated with polysaccharide colanic acid. Notably, this study also discovered for the first time that the luxS-deficiency dramatically attenuated adhesion and invasion to intestinal and brain cells, but ΔluxS subjected to desiccation could aggravate the cell virulence instead. Therefore, thinking the alteration of toxicity caused by low-moisture, approach based on blocking the expression of the luxS gene to prevent Cronobacter in LMF needs to be adopted with caution.