Contributions of Six Lineage-Specific Internalin-Like Genes to Invasion Efficiency of Listeria monocytogenes

Listeria monocytogenes strains are divided into at least three lineages, which seem to differ in virulence. Internalins are surface-attached or secreted proteins that encode leucine-rich repeats, and L. monocytogenes encodes species-specific as well as lineage-specific internalin and internalin-like genes. Internalins A and B have previously been shown to be critical for L. monocytogenes host cell invasion. Transcription of selected internalins is regulated by the virulence gene regulator PrfA and/or the stress-responsive alternative sigma factor σ^B. We hypothesized that lineage-specific internalin-like genes may contribute to differential virulence and niche adaptation of the L. monocytogenes lineages. Initial quantitative real time, reverse transcriptase PCR (RT-PCR) showed that the six selected lineage-specific internalin-like genes were transcribed in cells grown at 16° and 37°C. Lineage-specific internalin-like gene, lineage II (lsiIIX) showed significantly higher transcript levels in log-phase cells grown at 37°C as compared to 16°C. The gene lsiIA was preceded by a putative σ^B-dependent promoter and showed σ^B-dependent transcription. None of the null mutants in lineage-specific internalin-like genes differed from their respective parent strain in ability to invade either human intestinal epithelial or hepatocyte-like cell lines. All three mutants in lineage I–specific internalin-like genes exhibited the same growth condition–dependent invasion phenotype as their parent strain (∼1.5 log higher invasion efficiency when grown at 30°C without aeration versus 37°C with aeration). Despite structural similarities to internalins with known roles in host cell attachment and invasion, none of the six lineage-specific internalin-like genes characterized here appear to contribute to invasion. Combined with the observation that some nonpathogenic Listeria species also carry internalin genes, our findings suggest a broad role of Listeria internalins, not limited to attachment and invasion of human cells. Due to the wide host range of L. monocytogenes and the fact that transcription of internalin-like genes can differ considerably depending on growth condition, elucidating the function of different internalins and internalin-like genes will remain a challenge.