Project description:Listeria Persistence

Project description:Listeria monocytogenes causes severe foodborne illness in pregnant women and immunocompromised individuals. After the intestinal phase of infection, the liver plays a central role in the clearance of this pathogen through its important functions in immunity. However, recent evidence suggests that subpopulations of L. monocytogenes may escape eradication after prolonged infection of hepatocytes, by entering a persistence phase in vacuoles. Here, we examine whether this long-term infection alters hepatocyte defense pathways, which may be instrumental for bacterial persistence. We first established models of Listeria infection in human hepatocyte cell lines HepG2 and Huh7 and in primary mouse hepatocytes (PMH). In these cells, Listeria efficiently enters the persistence stage after a 3-day infection, while inducing a type I (PMH) or type I/III (HepG2) or no (Huh7) interferon response. RNA-seq analysis identified a common signature of long-term Listeria infection on the hepatocyte transcriptome, characterized by overexpression of a set of genes involved in antiviral immunity and under-expression of many acute phase protein (APP) genes, particularly involved in the complement and coagulation systems. The decrease in APP transcript amounts correlated with lower protein abundance in the secretome of infected cells, as shown by proteomics, and also occurred in the presence of APP inducers (IL-6 or IL-1b). The results also suggest that long-term Listeria infection affects lipid metabolism pathways. Collectively, these results reveal that long-term infection with L. monocytogenes profoundly deregulates the innate immune functions of hepatocytes, which could generate an environment favorable to the establishment of persistent infection.

Project description:Genome analysis of persistent Listeria monocytogenes strains

Project description:Genomics of Listeria monocytogenes isolates persistent in food processing sites

Project description:Persistence of Listeria monocytogenes in retail deli environments is a serious food safety issue, potentially leading to cross-contamination of ready-to-eat foods such as deli meats, salads, and cheeses. We previously discovered strong evidence of L. monocytogenes persistence in delis across multiple states. We hypothesized that this was correlated with isolates’ innate characteristics, such as biofilm-forming capacity or gene differences.We further chose four isolates for RNA-sequencing analysis and compared their global biofilm transcriptome to their global planktonic transcriptome. Analysis of biofilm vs planktonic gene expression did not show the expected differences in gene expression patterns. Overall, L. monocytogenes persistence in the deli environment is likely a matter of poor sanitation and/or facility design, rather than isolates’ biofilm-forming capacity, sanitizer tolerance, or genomic content

Project description:Markers of persistence and virulence in Canadian Listeria monocytogenes food and clinical isolates

Project description:Phosphopeptides were identified in Listeria monocytogesn strain constitutivally expressing PrfA. Also, the phosphoproteins and proteins were identified that are overexpressed/underextressed in response to PrfA.

Project description:Dissecting Listeria monocytogenes persistence and transmission in a retail market using whole-genome sequencing

Project description:ISG15 is primarily documented as an interferon-stimulated, ubiquitin-like protein (ubl), which has anti-viral activity. Although ISG15 was the founding member of the ubl protein family, very little is known about its function. We have found that ISG15 expression in non-phagocytic cells is dramatically induced upon Listeria infection and that surprisingly this induction can be Type I Interferon independent. Listeria-mediated ISG15 induction depends on the cytosolic surveillance pathway, which senses bacterial DNA and signals through STING, TBK1, IRF3 and IRF7. Most importantly, we observed that ISG15 expression restricts Listeria infection both in vitro and in vivo. We then made use of Stable Isotope Labeling in tissue culture (SILAC) to identify the ISGylated proteins that could be responsible for the ISG15-mediated protective effect. Our SILAC analysis revealed that overexpression of ISG15 leads to a striking ISGylation of integral membrane proteins of the endoplasmic reticulum and Golgi apparatus, which correlates with increased canonical secretion of cytokines. Taken together, our data reveal a previously uncharacterized signaling pathway that restricts Listeria infection and acts via ISGylation, reinforcing the view that ISG15 is a key component of the innate immune arsenal of the mammalian host.

Project description:Adaptation of Listeria weihenstephanensis to anaerobiosis. Trascriptional profiling at two different temperatures of L. weihenstephanensis