Recent foodborne outbreaks have linked infection by enterohemorrhagic Escherichia coli (EHEC) serotype O157:H7 to the consumption of contaminated lettuce. Contamination via food handler error and on-the-farm contamination are thought to be responsible for several outbreaks. Though recent studies have examined the application of EHEC to store-bought lettuce, little is known about the attachment of EHEC to growing plants. We investigated the association of lettuce seedlings with EHEC O157:H7 strains implicated in lettuce or fruit outbreaks using hydroponic and soil model systems. EHEC strains that express the green fluorescent protein were observed by stereomicroscopy and confocal laser scanning microscopy to determine adherence patterns on growing lettuce seedlings. Bacteria adhered preferentially to plant roots in both model systems and to seed coats in the hydroponic system. Two of five nonpathogenic E. coli strains showed decreased adherence to seedling roots in the hydroponic system. EHEC was associated with plants in as few as 3 days in soil, and contamination levels were dose-dependent. EHEC levels associated with young plants inoculated with a low dose suggested that the bacteria had multiplied. These data suggest that preharvest crop contamination via contaminated irrigation water can occur through plant roots.
We have developed two sets of Campylobacter shuttle vectors containing either the gfp (green fluorescent protein), yfp (yellow fluorescent protein), or cfp (cyan fluorescent protein) reporter gene. In one set, the reporter gene is fused to a consensus Campylobacter promoter sequence (P c ). The other set contains a pUC18 multicloning site upstream of the reporter gene, allowing the construction of transcriptional fusions using known promoters or random genomic fragments. C. jejuni cells transformed with the P c fusion plasmids are strongly fluorescent and easily visualized on chicken skin, on plant tissue, and within infected Caco-2 cells. In each C. jejuni strain tested, these plasmids were maintained over several passages in the absence of antibiotic selection. Also, in many C. jejuni strains, >91% of the cells transformed with the P c fusion plasmids remained fluorescent after several days. Experiments with yellow fluorescent and cyan fluorescent C. jejuni transformants suggest that aggregates containing two or more strains of C. jejuni may be present in an enrichment broth culture. Colonies arising from these aggregates would be heterologous in nature; therefore, isolation of a pure culture of C. jejuni, by selecting single colonies, from an environmental sample may not always yield a single strain.
Yersinia enterocolitica is an enteric pathogen that has served as a model system for the study of microbial pathogenesis. Numerous virulence gene have been identified both on the virulence plasmid and on the chromosome. One of the chromosomal genes that is highly correlated with virulence is ail, a gene identified along with inv in a screen for Y. enterocolitica genes that could confer an invasive phenotype to Escherichia coli. Ail also promotes serum resistance in both E. coli and Y. enterocolitica. Several virulence factors homologous to Ail have been identified in other pathogens, yet very little is known about what constitutes the functional domain(s) of these proteins. Proteins in this family are predicted to consist of eight transmembrane β‐sheets and four cell surface‐exposed loops. We constructed and characterized a number of insertion, deletion and point mutations in the regions of ail predicted to encode the cell surface loops. The results from the analysis of these mutants indicate that cell surface loops one and four do not directly promote invasion or serum resistance, whereas mutations in loop three appear to modulate both phenotypes. Analysis of mutations in loop 2 suggests that this surface‐exposed loop contains sequences required for serum resistance and invasion. In addition, a peptide derived from the sequence of loop 2 was able specifically to inhibit Ail‐mediated invasion in a dose‐dependent manner. These results suggest that Ail directly promotes invasion and that loop 2 contains an active site, perhaps a receptor‐binding domain. Analyses of the mutations also suggest that the serum resistance and invasion phenotypes may be separable, because there are numerous mutations that affect one phenotype but not the other.
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