Investigation of specific substitutions in virulence genes characterizing phenotypic groups of low-virulence field strains of Listeria monocytogenes.

Several models have shown that virulence varies from one strain of Listeria monocytogenes to another, but little is known about the cause of low virulence. Twenty-six field L. monocytogenes strains were shown to be of low virulence in a plaque-forming assay and in a subcutaneous inoculation test in mice. Using the results of cell infection assays and phospholipase activities, the low-virulence strains were assigned to one of four groups by cluster analysis and then virulence-related genes were sequenced. Group I included 11 strains that did not enter cells and had no phospholipase activity. These strains exhibited a mutated PrfA; eight strains had a single amino acid substitution, PrfAK220T, and the other three had a truncated PrfA, PrfADelta174-237. These genetic modifications could explain the low virulence of group I strains, since mutated PrfA proteins were inactive. Group II and III strains entered cells but did not form plaques. Group II strains had low phosphatidylcholine phospholipase C activity, whereas group III strains had low phosphatidylinositol phospholipase C activity. Several substitutions were observed for five out of six group III strains in the plcA gene and for one out of three group II strains in the plcB gene. Group IV strains poorly colonized spleens of mice and were practically indistinguishable from fully virulent strains on the basis of the above-mentioned in vitro criteria. These results demonstrate a relationship between the phenotypic classification and the genotypic modifications for at least group I and III strains and suggest a common evolution of these strains within a group.

The autolysin Ami contributes to the adhesion of Listeria monocytogenes to eukaryotic cells via its cell wall anchor.

Adherence of pathogenic microorganisms to the cell surface is a key event during infection. We have previously reported the characterization of Listeria monocytogenes transposon mutants defective in adhesion to eukaryotic cells. One of these mutants had lost the ability to produce Ami, a 102 kDa autolytic amidase with an N-terminal catalytic domain and a C-terminal cell wall-anchoring domain made up of repeated modules containing the dipeptide GW ('GW modules'). We generated ami null mutations by plasmid insertion into L. monocytogenes strains lacking the invasion proteins InlA (EGDDeltainlA), InlB (EGDDeltainlB) or both (EGDDeltainlAB). These mutants were 5-10 times less adherent than their parental strains in various cell types. The adhesion capacity of the mutants was restored by complementation with a DNA fragment encoding the Ami cell wall-anchoring domain fused to the Ami signal peptide. The cell-binding activity of the Ami cell wall-anchoring domain was further demonstrated using the purified polypeptide. Growth of the ami null mutants constructed in EGD and EGDDeltainlAB backgrounds was attenuated in the livers of mice inoculated intravenously, indicating a role for Ami in L. monocytogenes virulence. Adhesive properties have recently been reported in the non-catalytic domain of two other autolysins, Staphylococcus epidermidis AtlE and Staphylococcus saprophyticus Aas. Interestingly, we found that these domains were also composed of repeated GW modules. Thus, certain autolysins appear to promote bacterial attachment by means of their GW repeat domains. These molecules may contribute to the colonization of host tissues by Gram-positive bacteria.

ClpC ATPase is required for cell adhesion and invasion of Listeria monocytogenes.

We studied the role of two members of the 100-kDa heat shock protein family, the ClpC and ClpE ATPases, in cell adhesion and invasion of the intracellular pathogen Listeria monocytogenes. During the early phase of infection, a clpC mutant failed to disseminate to hepatocytes in the livers of infected mice whereas the invasive capacity of a clpE mutant remained unchanged. This was confirmed by a confocal microscopy study on infected cultured hepatocyte and epithelial cell lines, showing a strong reduction of cell invasion only by the clpC mutant. Western blot analysis with specific antisera showed that the absence of ClpC, but not that of ClpE, reduced expression of the virulence factors InlA, InlB, and ActA. ClpC-dependent modulation of these factors occurs at the transcriptional level with a reduction in the transcription of inlA, inlB, and actA in the clpC mutant, in contrast to the clpE mutant. This work provides the first evidence that, in addition to promoting escape from the phagosomes, ClpC is required for adhesion and invasion and modulates the expression of InlA, InlB, and ActA, further supporting the major role of the Clp chaperones in the virulence of intracellular pathogens.