Dithiothreitol enhances Listeria monocytogenes mediated cell cytotoxicity.

The hybridoma Ped-2E9 based cytotoxicity assay was developed to distinguish virulent from avirulent Listeria species in 6 hr. The cytotoxicity effect on Ped-2E9 was reported to be primarily due the cytolytic action of listeriolysin O (LLO), produced by L. monocytogenes. In this study, the effect of a reducing agent, dithiothreitol (DTT, 0-2 mM) that is known to activate LLO was investigated to make the Ped-2E9 based cytotoxicity assay an even more sensitive and rapid. Also, we examined the effect of fetal bovine serum (FBS, 0-50%), a common ingredient of tissue culture media on cytotoxicity. A DTT concentration of 0.5 mM gave an optimum cytotoxicity effect, which could be measured by both alkaline phosphatase (AP) and lactate dehydrogenase (LDH) assays in just 1.5-2 hr. FBS, at levels between 10 to 50%, significantly inhibited Listeria-mediated cytotoxicity. Concentrated culture filtrates from L. monocytogenes or LLO producing recombinant L. innocua (prfA+ hlyA+) strain also caused cytotoxicity effects, which were observed by scanning electron microscopy or a cytotoxicity assay in 2-3 hr. Interestingly, addition of DTT to culture filtrates produced 100% cell cytotoxicity in just 15 min. This indicated that LLO activity, which is responsible for Ped-2E9 cytotoxicity, was augmented several folds with the addition of a reducing agent. Examination of Listeria isolates belonging to different serogroups from clinical sources or naturally contaminated meat products with DTT gave cytotoxicity results in 2 hr, which were comparable to the 5-hr assay analyzed concurrently without DTT. These results indicated that DTT, which activated the LLO, could be used in the cytotoxicity assay to enhance Listeria-mediated Ped-2E9 cell cytotoxicity. This knowledge will greatly assist us to develop a user-friendly rapid assay to screen cytopathogenic properties of Listeria species.

Surface protein p104 is involved in adhesion of Listeria monocytogenes to human intestinal cell line, Caco-2.

Adhesion of Listeria monocytogenes to intestinal endothelial cells is an important initial event in the pathogenesis of infection which is not well understood. The suggestion has been made that some proteins, including internalin and actin polymerisation protein (ActA), and carbohydrate molecules mediate, at least in part, the adhesion of listeria to certain cultured mammalian cells. This study investigated the role of a L. monocytogenes cell-surface protein of 104 kDa (p104) in adhesion to human intestinal enterocyte-like Caco-2 cell lines by transposon (Tn916) mutagenesis and a p104-specific monoclonal antibody (MAb-H7). Genotypic and phenotypic characteristics of Tn916-transformed L. monocytogenes strains, AAMU530 and AAMU572, revealed that these strains did not express p104, and the transposon had been inserted at a single locus in the structural gene. Strains AAMU530 and AAMU572 yielded only 10 and 6.3% adhesion to Caco-2 cells. Coating of L. monocytogenes and L. innocua wild-type strains with MAb-H7 reduced adhesion to Caco-2 cells from 100% to 50 and 45%, respectively, whereas on isotype control MAb EM-7G1 had no effect. Western blot analysis with MAb-H7 indicated that p104 is present in all Listeria spp. except in L. grayi. Furthermore, p104 is also present in internalin (BUG8) and ActA (LUT12) deficient strains, suggesting that p104 is indeed different from internalin or ActA proteins. Cytotoxicity analysis of strains AAMU530 and AAMU572 demonstrated that these strains, although haemolytic and phospholipase-positive, were avirulent when tested with a hybridoma B-lymphocyte cell line. Loss of virulence could be attributed to the interruption of adhesion of mutant strains to the hybridoma cell line. These results strongly suggest that p104 is an adhesion factor in L. monocytogenes and possibly in other Listeria species and is involved in adhesion to intestinal cells.

Alkaline phosphatase release assay to determine cytotoxicity for Listeria species.

A simple cytotoxicity assay for Listeria species was developed by assaying alkaline phosphatase (AP) release from an infected hybrid B lymphocyte (Ped-2E9) line. Eight of eight L. monocytogenes and six of 11 L. ivanovii strains induced significantly high AP release from Ped-2E9 cells compared to five other L. ivanovii strains and other Listeria spp. In contrast, all L. monocytogenes and L. ivanovii test strains showed high release of lactate dehydrogenase (LDH) activity from Ped-2E9 cells. The molecular mass of AP was estimated to be about 128-165 kDa, suggesting severe membrane damage in Ped-2E9 cells due to Listeria infection. The data presented here indicate that AP assay could be used over LDH assay to detect Listeria-induced cell cytotoxicity.

Frozen stored murine hybridoma cells can be used to determine the virulence of Listeria monocytogenes.

Murine hybridoma cells, designated Ped-2E9, when stored up to 60 days at -196 degrees C or up to 48 days at -80 degrees C, gave results equivalent to those for freshly grown murine hybridoma cells in an in vitro pathogenicity assay of Listeria species. Thus, laboratories do not need to have their own tissue culture facilities to maintain the hybridoma cells for the assay described.

A six-hour in vitro virulence assay for Listeria monocytogenes using myeloma and hybridoma cells from murine and human sources.

An in vitro cell culture assay using myeloma cells and hybrid lymphocytes was developed which detected pathogenic Listeria strains in just 6 h. Three separate hybridoma cell lines, murine Ped-2E9 and EM-7G1 and human RI.37 and murine myeloma NS1 cells, proved equally sensitive in responding to virulent Listeria species. Listeria monocytogenes along with other Listeria spp., collected from food and clinical sources, were inoculated at 10(8) cfu/ml into a suspension of Ped-2E9 (10(6)/ml). Pathogenic Listeria spp. killed 80% of hybridoma cells by 4 h, as determined by trypan blue exclusion test. Conversely, none of all nonpathogenic Listeria spp. killed the hybridoma cells. Ped-2E9 cells exposed to three strains of L. monocytogenes strains showed 96-97.5% death in 6 h measured by trypan blue staining and release of 91-97% of lactate dehydrogenase (LDH) enzyme. RI.37 cells showed similar results. A multiplicity of exposure (MOE) of 100 L. monocytogenes to 1 hybridoma cell or of 10:1 killed about 80% of the hybridoma cells in 4 or 6 h respectively. The in vitro virulence assay of L. monocytogenes with hybridoma cells compared favorably with the immunocompromised mouse model, yielding results in 6 h instead of 3 days. Intracellular L. monocytogenes and L. innocua were not recovered from Ped-2E9 hybridoma cells after 2 or 4 h of exposure. However, attachment of both L. monocytogenes and L. innocua cells on Ped-2E9 cell surfaces were observed under epifluorescence microscopy. Direct contact of hemolysin positive L. monocytogenes with hybridoma cells is essential to cause death, since hybridoma cells were not killed when they were separated from the growing bacteria by a 0.45 microns filter.