Entry of the bacterial pathogen Listeria monocytogenes into mammalian cells

The bacterial pathogen Listeria monocytogenes causes food-borne illnesses leading to meningitis or abortion. Listeria provokes its internalization ('entry') into mammalian cells that are normally non-phagocytic, such as intestinal epithelial cells and hepatocytes. Entry provides access to a nutrient-rich cytosol and allows translocation across anatomical barriers. Here I discuss the two major internalization pathways used by Listeria. These pathways are initiated by binding of the bacterial surface proteins InlA or InlB to their respective host receptors, E-cadherin or Met. InlA mediates traversal of the intestinal barrier, whereas InlB promotes infection of the liver. At the cellular level, both InlA- and InlB-dependent entry require host signalling that promotes cytoskeletal rearrangements and pathogen engulfment. However, many of the specific signalling proteins in the two entry routes differ. InlA-mediated uptake uses components of adherens junctions that are coupled to F-actin and myosin, whereas InlB-dependent entry involves cytosolic adaptors that bridge Met to regulators of F-actin, including phosphoinositide 3-kinase and activators of the Arp2/3 complex. Unexpectedly, entry directed by InlB also involves endocytic components. Future work on InlA and InlB will lead to a better understanding of virulence, and may also provide novel insights into the normal biological functions of E-cadherin and Met.     

Species specificity of the Listeria monocytogenes InlB protein

InlA and InlB mediate L. monocytogenes entry into eukaryotic cells. InlA is required for the crossing of the intestinal and placental barriers. InlA uses E-cadherin as receptor in a species-specific manner. The human E-cadherin but not the mouse E-cadherin is a receptor for InlA. In human cells, InlB uses Met and gC1qR as receptors. By studying the role of InlB in vivo, we found that activation of Met by InlB is species-specific. In mice, InlB is important for liver and spleen colonization, but not for the crossing of the intestinal epithelium. Strikingly, the virulence of a DeltainlB deletion mutant is not attenuated in guinea pigs and rabbits. Guinea pig and rabbit cell lines do not respond to InlB, although expressing Met and gC1qR, but support InlB-mediated responses upon human Met gene transfection, indicating that InlB does not recognize or stimulate guinea pig and rabbit Met. In guinea pig cells, the effect of human Met gene transfection on InlB-dependent entry is increased upon cotransfection with human gc1qr gene, showing the additive roles of gC1qR and Met. These results unravel a second L. monocytogenes species specificity critical for understanding human listeriosis and emphasize the need for developing new animal models for studying InlA and InlB functions in the same animal model.     

Exploitation of host cell cytoskeleton and signalling during Listeria monocytogenes entry into mammalian cells

Deciphering how Listeria monocytogenes exploits the host cell machinery to invade mammalian cells during infection isa key issue for the understanding how this food-borne pathogen causes a pleiotropic disease ranging from gastro-enteritis to meningitis and abortions. Using multidisciplinary approaches, essentially combining bacterial genetics and cell biology, we have identified two bacterial proteins critical for entry into target cells, InlA and InlB. Their cellular ligands have been also identified: InlA interacts with the adhesion molecule E-cadherin, while InlB interacts with the receptor for the globular head of the complement factor Clq (gClq-R), with the hepatocyte growth factor receptor (c-Met) and with glycosaminoglycans(including heparan sulphate). The dynamic interaction between these cellular receptors and the actin cytoskeleton is currently under investigation. Several intracellular molecules have been recognized as key effectors for Listeria entry into target cells,including catenins (implicated in the connection of E-cadherin to actin) and the actin depolymerising factor/cofilin (involved in the rearrangement of the cytoskeleton in the InlB-dependent internalisation pathway). At the organism level, species specificity has been discovered concerning the interaction between InlA and E-cadherin, leading to the generation of transgenic mice expressing the human E-cadherin, in which the critical role of InlA in the crossing of the intestinal barrier has been clearly determined. Listeria appears as an instrumental model for addressing critical questions concerning both the complex process of bacterial pathogenesis and also fundamental molecular processes, such as phagocytosis.     

Exploitation of host cell cytoskeleton and signalling during Listeria monocytogenes entry into mammalian cells

Deciphering how Listeria monocytogenes exploits the host cell machinery to invade mammalian cells during infection is a key issue for the understanding how this food-borne pathogen causes a pleiotropic disease ranging from gastro-enteritis to meningitis and abortions. Using multidisciplinary approaches, essentially combining bacterial genetics and cell biology, we have identified two bacterial proteins critical for entry into target cells, InlA and InlB. Their cellular ligands have been also identified: InlA interacts with the adhesion molecule E-cadherin, while InlB interacts with the receptor for the globular head of the complement factor C1q (gC1q-R), with the hepatocyte growth factor receptor (c-Met) and with glycosaminoglycans (including heparan sulphate). The dynamic interaction between these cellular receptors and the actin cytoskeleton is currently under investigation. Several intracellular molecules have been recognized as key effectors for Listeria entry into target cells, including catenins (implicated in the connection of E-cadherin to actin) and the actin depolymerising factor/cofilin (involved in the rearrangement of the cytoskeleton in the InlB-dependent internalisation pathway). At the organism level, species specificity has been discovered concerning the interaction between InlA and E-cadherin, leading to the generation of transgenic mice expressing the human E-cadherin, in which the critical role of InlA in the crossing of the intestinal barrier has been clearly determined. Listeria appears as an instrumental model for addressing critical questions concerning both the complex process of bacterial pathogenesis and also fundamental molecular processes, such as phagocytosis.     

Invasion of mammalian cells by Listeria monocytogenes: functional mimicry to subvert cellular functions

The bacterium Listeria monocytogenes has the unusual capacity to enter and to multiply in nonphagocytic cells. Bacterially induced phagocytosis is triggered mainly by the two surface proteins internalin (also called InlA) and InlB, which interact with host cell receptors and either mimic or act in place of the normal cellular ligands. Internalin interacts specifically with human E-cadherin, whereas InlB activates the tyrosine kinase receptor Met and also interacts with the ubiquitous receptor gC1qR and proteoglycans. Signals induced by crosstalk between the bacterium and the host cell allow internalization, which is a prelude to intracellular multiplication, actin-based movement and spread of the bacterium from cell to cell. Manipulating the bacterial invasion proteins offers us an unprecedented tool with which to understand the complex phenomenon of phagocytosis.     

The surface proteins InlA and InlB are interdependently required for polar basolateral invasion by Listeria monocytogenes in a human model of the blood–cerebrospinal fluid barrier

The Gram-positive bacterium Listeria monocytogenes can enter the human central nervous system and cause life-threatening meningitis. During this process the pathogen has to invade and cross diverse cellular barriers involving the functions of the surface proteins Internalin (InlA) and InlB. Whereas the internalin-dependent crossing of the intestinal epithelium and the fetoplacental barrier have been subject to intensive investigation, limited research elucidating the crossing of the human blood–cerebrospinal fluid barrier (BCSFB) has been reported. We have recently established a functional in vitro model of the BCSFB based on human choroid plexus papilloma (HIBCPP) cells. We show polarized expression of receptors involved in listerial invasion (i.e. E-Cadherin, Met) in HIBCPP cells. Infecting HIBCPP cells with the L. monocytogenes strain EGD, we demonstrate polar invasion exclusively from the in vivo relevant basolateral cell side. Intracellular listeria were found in vacuoles and the cytoplasm, where they were often associated with “actin tail”-like structures. Furthermore, the L. monocytogenes wild type strain shows significantly higher internalization rates than isogenic mutants lacking either InlA, InlB or both surface proteins. Deletion of either one or both proteins leads to a similarly decreased invasion, suggesting an interdependent function of InlA and InlB during invasion of choroid plexus epithelial cells.     

The InlB protein of Listeria monocytogenes is sufficient to promote entry into mammalian cells

InlB is one of the two Listeria monocytogenes invasion proteins required for bacterial entry into mammalian cells. Entry into human epithelial cells such as Caco-2 requires InlA, whereas InlB is needed for entry into cultured hepatocytes and some epithelial or fibroblast cell lines such as Vero, HEp-2 and HeLa cells. InlB-mediated entry requires tyrosine phosphorylation, cytoskeletal rearrangements and activation of the host protein phosphoinositide (PI) 3-kinase, probably in response to engagement of a receptor. In this study, we demonstrate for the first time that InlB is sufficient to promote internalization. Indeed, coating of normally non-invasive bacteria or inert latex beads with InlB leads to internalization into mammalian cells. In addition, a soluble form of InlB also appears to promote uptake of non-invasive bacteria, albeit at a very low level. Similar to entry of L. monocytogenes , uptake of InlB-coated beads required tyrosine phosphorylation in the host cell, PI 3-kinase activity and cytoskeletal reorganization. Taken together, these data indicate that InlB is sufficient for entry of L. monocytogenes into host cells and suggest that this protein is an effector of host cell signalling pathways.     

Involvement of CD44v6 in InlB-dependent Listeria invasion

Listeria monocytogenes , a Gram-positive bacterium, is the causative agent for the disease called listeriosis. This pathogen utilizes host cell surface proteins such as E-cadherin or c-Met in order to invade eukaryotic cells. The invasion via c-Met depends on the bacterial protein InlB that activates c-Met phosphorylation and internalization mimicking in many regards HGF, the authentic c-Met ligand. In this paper, we demonstrate that the activation of c-Met induced by InlB is dependent on CD44v6, a member of the CD44 family of transmembrane glycoproteins. Inhibiting CD44v6 by means of a blocking peptide, a CD44v6 antibody or CD44v6-specific siRNA prevents the activation of c-Met induced by InlB. Subsequently, signalling, scattering and the entry of InlB-coated beads into host cells are also impaired by CD44v6 blocking reagents. For the entry process, ezrin, a protein that links the CD44v6 cytoplasmic domain to the cytoskeleton, is required as well. Most importantly, this collaboration between c-Met and CD44v6 contributes to the invasion of L. monocytogenes into target cells as demonstrated by a drastic decrease in bacterial invasion in the presence of blocking agents such as the CD44v6 peptide or antibody.     

Listerial invasion protein internalin B promotes entry into ileal Peyer's patches in vivo

Listeria monocytogenes (Lm) invades the host intestine using listerial invasion proteins, internalins. The in vivo role of internalin A (InlA) and internalin B (InlB) is reported here. Intragastric (i.g.) administration and ligated loop assays with ΔinlB-Lm demonstrated that a lack of InlB significantly attenuates the invasive ability of Lm into various organs. On the other hand, InlA(m)-Lm expressing a mutant InlA with two substitutions, S192N and Y369S, which has been reported to increase the affinity of InlA to mouse E-cadherin, resulted in little increase in intestinal infection according to both ligated loop and i.g. infection assays. Lm preferentially enters ileal Peyer's patch (PP) via M cells and ΔinlB-Lm showed severely reduced ability to invade though these cells. The present results reveal the importance of InlB, which accelerates listerial invasion into M cells on ileal PPs in vivo.     

Molecular mechanisms exploited by Listeria monocytogenes during host cell invasion

The facultative intracellular bacterial pathogen Listeria monocytogenes has evolved multiple strategies to invade a large panel of mammalian cells. Host cell invasion is critical for several stages of listeriosis pathology such as the initial crossing of the host intestinal barrier and the successive colonization of diverse target organs including the placenta. In this review, we address the main molecular mechanisms known to be used by L. monocytogenes during invasion of nonphagocytic cells and host tissues.     

Src, cortactin and Arp2/3 complex are required for E-cadherin-mediated internalization of Listeria into cells

Listeria monocytogenes is a food-borne pathogen able to invade non-phagocytic cells. InlA, a L. monocytogenes surface protein, interacts with human E-cadherin to promote bacterial entry. L. monocytogenes internalization is a dynamic process involving co-ordinated actin cytoskeleton rearrangements and host cell membrane remodelling at the site of bacterial attachment. Interaction between E-cadherin and catenins is required to promote Listeria entry, and for the establishment of adherens junctions in epithelial cells. Although several molecular factors promoting E-cadherin-mediated Listeria internalization have been identified, the proteins regulating the transient actin polymerization required at the bacterial entry site are unknown. Here we show that the Arp2/3 complex acts as an actin nucleator during the InlA/E-cadherin-dependent internalization. Using a variety of approaches including siRNA, expression of dominant negative derivatives and pharmacological inhibitors, we demonstrate the crucial role of cortactin in the activation of the Arp2/3 complex during InlA-mediated entry. We also show the requirement of the small GTPase Rac1 and that of Src-tyrosine kinase activity to promote Listeria internalization. Together, these data suggest a model in which Src tyrosine kinase and Rac1 promote recruitment of cortactin and activation of Arp2/3 at Listeria entry site, mimicking events that occur during adherens junction formation.     

Successive post-translational modifications of E-cadherin are required for InlA-mediated internalization of Listeria monocytogenes

Listeria monocytogenes surface proteins internalin (Inl)A and InlB interact with the junctional protein E-cadherin and the hepatocyte growth factor (HGF) receptor Met, respectively, on the surface of epithelial cells to mediate bacterial entry. Here we show that InlA triggers two successive E-cadherin post-translational modifications, i.e. the Src-mediated tyrosine phosphorylation of E-cadherin followed by its ubiquitination by the ubiquitin-ligase Hakai. E-cadherin ubiquitination induces the recruitment of clathrin that is required for optimal bacterial internalization. We also show that the initial clustering of E-cadherin at the bacterial entry site requires caveolin, a protein normally involved in clathrin-independent endocytosis. Strikingly clathrin and caveolin are also recruited at the site of entry of E-cadherin-coated sepharose beads and functional experiments demonstrate that these two proteins are required for bead entry. Together these results not only document how the endocytosis machinery is recruited and involved in the internalization of a zippering bacterium, but also strongly suggest a functional link between E-cadherin endocytosis and the formation of adherens junctions in epithelial cells.     

Interactions between Listeria monocytogenes and host mammalian cells

Bacterial pathogens have developed a variety of strategies to induce their own internalization into mammalian cells which are normally nonphagocytic. The Gram-positive bacterium Listeria monocytogenes enters into many cultured cell types using two bacterial surface proteins, InlA (internalin) and InlB. In both cases, entry takes place after engagement of a receptor and induction of a series of signaling events.     

Distinct protein patterns associated with Listeria monocytogenes InlA- or InlB-phagosomes

Internalization of Listeria monocytogenes into non-phagocytic cells is mediated by the interactions between the two bacterial invasion proteins InlA (internalin) and InlB and their cellular surface receptors E-cadherin and c-Met. To get an insight into all the cellular components necessary for uptake and early intracellular life, we undertook a global proteomic characterization of the early listerial phagosome in the human epithelial cell line LoVo. First, we proceeded to an immunocytochemical characterization of intracellular marker recruitment to phagosomes containing latex beads coated with InlA or InlB. E-cadherin and c-Met were, as expected, rapidly recruited to the phagosomal formation site. Phagosomes subsequently acquired the early endosomal antigen 1 (EEA1) and the lysosomal-associated membrane protein 1 (LAMP1), while presenting a more delayed enrichment of the lysosomal hydrolase cathepsin D. Early phagosomes devoid of lysosomal, endoplasmic reticulum and Golgi enzymatic activities could then be isolated by subcellular fractionation of LoVo cells. Two-dimensional gel electrophoresis (2DPAGE) revealed differences between the protein profiles of InlA- or InlB-phagosomes and those of early/late endosomes or lysosomes of naive LoVo cells. One major protein specifically recruited on the InlB-phagosomes was identified by mass spectrometry as MSF, a previously reported member of the septin family of GTPases. MSF forms filaments that co-localize with the actin cytoskeleton in resting cells and it is recruited to the entry site of InlB-coated beads. These results suggest that MSF is a putative effector of the InlB-mediated internalization of L. monocytogenes into host cells.     

Interactions of Listeria monocytogenes with mammalian cells during entry and actin-based movement: bacterial factors, cellular ligands and signaling.

Although <50 kb of its 3.3 megabase genome is known, Listeria monocytogenes has received much attention and an impressive amount of data has contributed in raising this bacterium among the best understood intracellular pathogens. The mechanisms that Listeria uses to enter cells, escape from the phagocytic vacuole and spread from one cell to another using an actin-based motility process have been analysed in detail. Several bacterial proteins contributing to these events have been identified, including the invasion proteins internalin A (InlA) and B (InlB), the secreted pore-forming toxin listeriolysin O (LLO) which promotes the escape from the phagocytic vacuole, and the surface protein ActA which is required for actin polymerization and bacterial movement. While LLO and ActA are critical for the infectious process and are not redundant with other listerial proteins, the precise role of InlA and InlB in vivo remains unclear. How InlA, InlB, LLO or ActA interact with the mammalian cells is beginning to be deciphered. The picture that emerges is that this bacterium uses general strategies also used by other invasive bacteria but has evolved a panel of specific tools and tricks to exploit mammalian cell functions. Their study may lead to a better understanding of important questions in cell biology such as ligand receptor signalling and dynamics of actin polymerization in mammalian cells.     

InlA- but not InlB-mediated internalization of Listeria monocytogenes by non-phagocytic mammalian cells needs the support of other internalins

To determine the contribution of the previously identified internalins, InlA, InlB, InlC, InlE, InlG, and InlH, to internalization of Listeria monocytogenes by non-professional phagocytic mammalian cells, we constructed mutants with various combinations of deletions in the respective inl genes. Internalization of these mutants into the epithelial-like Caco-2 and the microvascular endothelial HBMEC cell lines were studied. Deletion of the inlGHE gene cluster, or of the single genes, led to a two to fourfold increased internalization by HBMEC and other non-phagocytic mammalian cells. Invasion into HBMEC was totally blocked in the absence of InlB, and InlB-dependent internalization did not require the presence of any of the other internalins. Internalization by Caco-2 cells was reduced to a level of about 1% in the absence of InlA and InlB, and was most efficient in the presence of InlA, InlB and InlC and in the absence of InlG, InlH and InlE. InlB and InlA, in each case in the absence of the other internalins, led (compared with the wild-type strain) to reduced internalization of about 20% and less than 10% respectively. InlA-dependent internalization (in the absence of InlB) required the additional function of InlC and InlGHE. The deletion of inlGHE enhanced the expression of InlA and InlB. The increased amount of InlA led to an increase in early association of L. monocytogenes with Caco-2 cells without enhancing its uptake in the absence of the other internalins, whereas the larger amount of InlB did not enhance early association of L. monocytogenes with HBMEC but led to an increase in internalization of L. monocytogenes. The results suggest that InlB is able to induce phagocytosis in HBMEC and (at a lower efficiency) in Caco-2 cells by itself, but InlA needs the supportive functions of the other internalins to trigger phagocytosis. None of these internalins seems to be required for cell-to-cell spread by L. monocytogenes, as shown by microinjection of Caco-2 cells with appropriate inl mutants.     

Structure of internalin,a major invasion protein of Listeria monocytogenes,in complex with its human receptor E-cadherin

Listeria monocytogenes, a food-borne bacterial pathogen, enters mammalian cells by inducing its own phagocytosis. The listerial protein internalin (InlA) mediates bacterial adhesion and invasion of epithelial cells in the human intestine through specific interaction with its host cell receptor E-cadherin. We present the crystal structures of the functional domain of InlA alone and in a complex with the extracellular, N-terminal domain of human E-cadherin (hEC1). The leucine rich repeat (LRR) domain of InlA surrounds and specifically recognizes hEC1. Individual interactions were probed by mutagenesis and analytical ultracentrifugation. These include Pro16 of hEC1, a major determinant for human susceptibility to L. monocytogenes infection that is essential for intermolecular recognition. Our studies reveal the structural basis for host tro-pism of this bacterium and the molecular deception L. monocytogenes employs to exploit the E-cadherin system.     

The pore-forming toxin listeriolysin O mediates a novel entry pathway of L. monocytogenes into human hepatocytes

Intracellular pathogens have evolved diverse strategies to invade and survive within host cells. Among the most studied facultative intracellular pathogens, Listeria monocytogenes is known to express two invasins-InlA and InlB-that induce bacterial internalization into nonphagocytic cells. The pore-forming toxin listeriolysin O (LLO) facilitates bacterial escape from the internalization vesicle into the cytoplasm, where bacteria divide and undergo cell-to-cell spreading via actin-based motility. In the present study we demonstrate that in addition to InlA and InlB, LLO is required for efficient internalization of L. monocytogenes into human hepatocytes (HepG2). Surprisingly, LLO is an invasion factor sufficient to induce the internalization of noninvasive Listeria innocua or polystyrene beads into host cells in a dose-dependent fashion and at the concentrations produced by L. monocytogenes. To elucidate the mechanisms underlying LLO-induced bacterial entry, we constructed novel LLO derivatives locked at different stages of the toxin assembly on host membranes. We found that LLO-induced bacterial or bead entry only occurs upon LLO pore formation. Scanning electron and fluorescence microscopy studies show that LLO-coated beads stimulate the formation of membrane extensions that ingest the beads into an early endosomal compartment. This LLO-induced internalization pathway is dynamin-and F-actin-dependent, and clathrin-independent. Interestingly, further linking pore formation to bacteria/bead uptake, LLO induces F-actin polymerization in a tyrosine kinase-and pore-dependent fashion. In conclusion, we demonstrate for the first time that a bacterial pathogen perforates the host cell plasma membrane as a strategy to activate the endocytic machinery and gain entry into the host cell.     

A single amino acid in E-cadherin responsible for host specificity towards the human pathogen Listeria monocytogenes.

Human E-cadherin promotes entry of the bacterial pathogen Listeria monocytogenes into mammalian cells by interacting with internalin (InlA), a bacterial surface protein. Here we show that mouse E-cadherin, although very similar to human E-cadherin (85% identity), is not a receptor for internalin. By a series of domain-swapping and mutagenesis experiments, we identify Pro16 of E-cadherin as a residue critical for specificity: a Pro-->Glu substitution in human E-cadherin totally abrogates interaction, whereas a Glu-->Pro substitution in mouse E-cadherin results in a complete gain of function. A correlation between cell permissivity and the nature of residue 16 in E-cadherins from several species is established. The location of this key specificity residue in a region of E-cadherin not involved in cell-cell adhesion and the stringency of the interaction demonstrated here have important consequences not only for the understanding of internalin function but also for the choice of the animal model to be used to study human listeriosis: mouse, albeit previously widely used, and rat appear as inappropriate animal models to study all aspects of human listeriosis, as opposed to guinea-pig, which now stands as a small animal of choice for future in vivo studies.     

Listeria monocytogenes Internalin and E-cadherin: From Bench to Bedside

Listeria monocytogenes is a Gram-positive bacterium responsible for a severe infection associated with different clinical features (gastroenteritis, meningoencephalitis, and abortion in pregnant women). These pathologies are caused by the unusual capacity of the bacterium to cross three host barriers during infection and to invade nonphagocytic cells. To invade host cells, Listeria uses two proteins, InlA and InlB, which have specific receptors on the host-cell surface, E-cadherin and Met, respectively. Here, we discuss the specificity of the InlA–E-cadherin interaction, the signaling cascade activated on E-cadherin engagement by InlA, and the role of InlA and E-cadherin in the breaching of host barriers and the dissemination of the infection.Listeriosis is a potentially lethal food-borne infection with a mortality rate up to 30%. It has emerged as a significant human infection in industrialized countries along with the development of large-scale agro-industrial plants and refrigerated food. Opposite to most food-borne infections, listeriosis is rare but potentially very severe, because it remains often under-diagnosed at its early stages (Lecuit 2007). The etiological agent of listeriosis is Listeria monocytogenes, a Gram-positive bacterium that contaminates meat, dairy products, and ready to eat food. Upon ingestion of contaminated food, L. monocytogenes can colonize the intestine and gives rise to gastroenteritis in case of the absorption of a high inoculum. Strikingly, L. monocytogenes has the capacity to cross the intestinal barrier and disseminate to the mesenteric lymph nodes, spleen, and liver. In immunocompromised individuals, L. monocytogenes may replicate in the spleen and liver, cause prolonged and sustained bacteremia, cross the blood–brain barrier and the placental barrier, and disseminate to the brain and placenta, causing meningitis, encephalitis, abortion in pregnant women, and neonatal infections (Hamon et al. 2006; Bonazzi et al. 2009).The capacity of L. monocytogenes to cross multiple host barriers relies on the ability of the bacterium to invade nonphagocytic cells, such as epithelial cells, by interacting with host cell-surface receptors. Adhesion to host cells is a key step underlying bacterial pathogenicity and it is required to counteract the mechanical clearance at tissue surfaces provided by intestinal peristaltism and blood flow. Internalization allows persistence in a shielded niche, away from the soluble effectors of the host immune system (Cossart and Sansonetti 2004; Pizarro-Cerda and Cossart 2006), and access to target organs, as illustrated by L. monocytogenes (Bonazzi et al. 2009).Bacterial surface proteins that engage host receptors are generally called adhesins, although it is now clear that many of them not only mediate adhesion, but also bacterial internalization (Boyle and Finlay 2003; Hauck et al. 2006; Pizarro-Cerda and Cossart 2006). Adhesion to and internalization of L. monocytogenes within epithelial cells is mainly mediated by two bacterial surface protein members of the internalin family, namely internalin (InlA) and InlB, that use E-cadherin and Met as receptors, respectively, on the surface of host cells (Hamon et al. 2006; Pizarro-Cerda and Cossart 2006; Bonazzi et al. 2009). Upon receptor-mediated internalization, L. monocytogenes is engulfed into the cell and becomes surrounded by a tight phagocytic vacuole that the bacterium can lyse by means of the pore-forming toxin listeriolysin O (LLO). Once free in the cytoplasm of the host cell, L. monocytogenes uses the protein ActA to harness the actin polymerization machinery and facilitate its intracellular movement via the formation of so-called actin “comet tails.” Actin-based motility is fundamental for L. monocytogenes direct cell-to-cell spread, a typical feature that allows the dissemination of the infection to neighboring cells via the formation of plasma membrane protrusions. Once internalized by neighboring cells, L. monocytogenes is confined in a double-membrane vacuole from which it escapes to restart its life cycle (Fig. 1) (Hamon et al. 2006).Open in a separate windowFigure 1.The cell cycle of L. monocytogenes. (1) L. monocytogenes adheres to the surface of epithelial cells via the interactions of the surface proteins InlA and InlB with E-cadherin and the Met receptor, respectively. (2) On internalization, L. monocytogenes is engulfed in a phagocytic vacuole. (3) L. monocytogenes lyses vacuolar membranes by means of the toxin LLO. (4) L. monocytogenes uses the protein ActA to harness the actin polymerization machinery and facilitate its intracellular movement via the formation of so-called actin “comet tails.” (5) L. monocytogenes exploits actin-based motility for direct cell-to-cell spread to allow the dissemination of the infection to neighboring cells via the formation of plasma membrane protrusions. (6) Once internalized by neighboring cells, L. monocytogenes is confined in a double-membrane vacuole from which it escapes to restart its life cycle.Its remarkable adaptation to the cellular environment and its capacity to exploit cellular receptor-mediated signaling pathways and the actin polymerization machinery have made L. monocytogenes an exceptional tool for the study of a wide array of cellular functions (Cossart and Sansonetti 2004; Bonazzi and Cossart 2006; Hamon et al. 2006; Pizarro-Cerda and Cossart 2006; Veiga and Cossart 2005a; Bonazzi et al. 2009). Here, we review the interaction of InlA with E-cadherin, the signaling pathway initiated by this interaction that results in the internalization of L. monocytogenes, and the role of InlA-E-cadherin interaction during listeriosis.