Strain-Specific Interactions of Listeria monocytogenes with the Autophagy System in Host Cells

Listeria monocytogenes is an intracellular bacterial pathogen that can replicate in the cytosol of host cells. These bacteria undergo actin-based motility in the cytosol via expression of ActA, which recruits host actin-regulatory proteins to the bacterial surface. L. monocytogenes is thought to evade killing by autophagy using ActA-dependent mechanisms. ActA-independent mechanisms of autophagy evasion have also been proposed, but remain poorly understood. Here we examined autophagy of non-motile (ΔactA) mutants of L. monocytogenes strains 10403S and EGD-e, two commonly studied strains of this pathogen. The ΔactA mutants displayed accumulation of ubiquitinated proteins and p62/SQSTM1 on their surface. However, only strain EGD-e ΔactA displayed colocalization with the autophagy marker LC3 at 8 hours post infection. A bacteriostatic agent (chloramphenicol) was required for LC3 recruitment to 10403S ΔactA, suggesting that these bacteria produce a factor for autophagy evasion. Internalin K was proposed to block autophagy of L. monocytogenes in the cytosol of host cells. However, deletion of inlK in either the wild-type or ΔactA background of strain 10403S had no impact on autophagy evasion by bacteria, indicating it does not play an essential role in evading autophagy. Replication of ΔactA mutants of strain EGD-e and 10403S was comparable to their parent wild-type strain in macrophages. Thus, ΔactA mutants of L. monocytogenes can block killing by autophagy at a step downstream of protein ubiquitination and, in the case of strain EGD-e, downstream of LC3 recruitment to bacteria. Our findings highlight the strain-specific differences in the mechanisms that L. monocytogenes uses to evade killing by autophagy in host cells.     

Listeria monocytogenes Evades Killing by Autophagy During Colonization of Host Cells

Listeria monocytogenes is an intracellular pathogen that is able to colonize the cytosol of macrophages. Here we examined the interaction of this pathogen with autophagy, a host cytosolicdegradative pathway that constitutes an important component of innate immunity towards microbial invaders. L. monocytogenes infection induced activation of the autophagy system in macrophages. At 1 h post infection (p.i.), a population of intracellular bacteria (~37%) colocalized with the autophagy marker LC3. These bacteria were within vacuoles and were targeted by autophagy in an LLO-dependent manner. At later stages in infection (by 4 h p.i.), the majority of L. monocytogenes escaped into the cytosol and rapidly replicated. At these times, less than 10% of intracellular bacteria colocalized with LC3. We found that ActA expression was sufficient to prevent autophagy of bacteria in the cytosol of macrophages. Surprisingly, ActA expression was not strictly necessary, indicating that other virulence factors were involved. Accordingly, we also found a role for the bacterial phospholipases, PI-PLC and PC-PLC, in autophagy evasion, as bacteria lacking phospholipase expression were targeted by autophagy at later times in infection. Together, our results demonstratethat L. monocytogenes utilizes multiple mechanisms to avoid destruction by the autophagy system during colonization of macrophages.     

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.     

Autophagy Limits Listeria monocytogenes Intracellular Growth in the Early Phase of Primary Infection

Autophagy has been recently proposed to be a component of the innate cellular immune response against several types of intracellular microorganisms. However, other intracellular bacteria including Listeria monocytogenes have been thought to evade the autophagic cellular surveillance. Here, we show that cellular infection by L. monocytogenes induces an autophagic response, which inhibits the growth of both the wild-type and a delta actA mutant strain, the latter being impaired in cell-to-cell spreading. The onset of early intracellular growth is accelerated in autophagy-deficient cells, but the growth rate once bacteria begin to multiply in the cytosol does not change. Moreover, a significant fraction of the intracellular bacteria co-localize with autophagosomes at the early time-points after infection. Thus, autophagy targets L. monocytogenes during primary infection by limiting the onset of early bacterial growth. The bacterial expression of listeriolysin O but not phospholipases is necessary for the induction of autophagy, suggesting a possible role for permeabilization of the vacuole in the induction of autophagy. Interestingly, the growth of a delta plcA/B L. monocytogenes strain deficient for bacterial phospholipases is impaired in wild-type cells, but restored in the absence of autophagy, suggesting that bacterial phospholipases may facilitate the escape of bacteria from autophagic degradation. We conclude that L. monocytogenes are targeted for degradation by autophagy during the primary infection, in the early phase of the intracellular cycle, following listeriolysin O-dependent vacuole perforation but preceding active multiplication in the cytosol, and that expression of bacterial phospholipases is necessary for the evasion of autophagy.     

Autophagy limits Listeria monocytogenes intracellular growth in the early phase of primary infection

Autophagy has been recently proposed to be a component of the innate cellular immune response against several types of intracellular microorganisms. However, other intracellular bacteria including Listeria monocytogenes have been thought to evade the autophagic cellular surveillance. Here, we show that cellular infection by L. monocytogenes induces an autophagic response, which inhibits the growth of both the wild-type and a DeltaactA mutant strain, impaired in cell-to-cell spreading. The onset of early intracellular growth is accelerated in autophagy-deficient cells, but the growth rate once bacteria begin to multiply in the cytosol does not change. Moreover, a significant fraction of the intracellular bacteria colocalize with autophagosomes at the early time-points after infection. Thus, autophagy targets L. monocytogenes during primary infection by limiting the onset of early bacterial growth. The bacterial expression of listeriolysin O but not phospholipases is necessary for the induction of autophagy, suggesting a possible role for permeabilization of the vacuole in the induction of autophagy. Interestingly, the growth of a DeltaplcA/B L. monocytogenes strain deficient for bacterial phospholipases is impaired in wild-type cells, but restored in the absence of autophagy, suggesting that bacterial phospholipases may facilitate the escape of bacteria from autophagic degradation. We conclude that L. monocytogenes are targeted for degradation by autophagy during the primary infection, in the early phase of the intracellular cycle, following listeriolysin O-dependent vacuole perforation but preceding active multiplication in the cytosol, and that expression of bacterial phospholipases is necessary for the evasion of autophagy.     

Actin filament nucleation by the bacterial pathogen, Listeria monocytogenes

Shortly after Listeria is phagocytosed by a macrophage, it dissolves the phagosomal membrane and enters the cytoplasm. 1 h later, actin filaments coat the Listeria and then become rearranged to form a tail with which the Listeria moves to the macrophage surface as a prelude to spreading. If infected macrophages are treated with cytochalasin D, all the actin filaments associated with the Listeria break down leaving a fine, fibrillar material that does not decorate with subfragment 1 of myosin. This material is associated with either the surface of the Listeria (the cloud stage) or one end (the tail stage). If the cytochalasin-treated infected macrophages are detergent extracted and then incubated in nuclei-free monomeric actin under polymerizing conditions, actin filaments assemble from the fine, fibrillar material, the result being that each Listeria has actin filaments radiating from its surface like the spokes of a wheel (cloud form) or possesses a long tail of actin filaments formed from the fine, fibrillar material located at one end of the Listeria. Evidence that the fine fibrillar material is involved in nucleating actin assembly comes from a Listeria mutant. Although the mutant replicates at a normal rate in macrophages, actin filaments do not form on its surface (cloud stage) or from one end (tail stage), nor does the bacterium spread. Furthermore it does not form the fine fibrillar material. Evidence that the nucleating material is a secretory product of Listeria and not the macrophage comes from experiments using chloramphenicol, which inhibits protein synthesis in Listeria but not in macrophages. If chloramphenicol is applied 1 h after infection, a time before actin filaments are found attached to the Listeria in untreated macrophages, actin filaments never assemble on the Listeria even when fixed 3 h later. Furthermore the fine fibrillar material is absent, although there is a coat of dense granular material.     

Listeriolysin O Is Necessary and Sufficient to Induce Autophagy during Listeria monocytogenes Infection

Background

Recent studies have suggested that autophagy is utilized by cells as a protective mechanism against Listeria monocytogenes infection.

Methodology/Principal Findings

However we find autophagy has no measurable role in vacuolar escape and intracellular growth in primary cultured bone marrow derived macrophages (BMDMs) deficient for autophagy (atg5^−/−). Nevertheless, we provide evidence that the pore forming activity of the cholesterol-dependent cytolysin listeriolysin O (LLO) can induce autophagy subsequent to infection by L. monocytogenes. Infection of BMDMs with L. monocytogenes induced microtubule-associated protein light chain 3 (LC3) lipidation, consistent with autophagy activation, whereas a mutant lacking LLO did not. Infection of BMDMs that express LC3-GFP demonstrated that wild-type L. monocytogenes was encapsulated by LC3-GFP, consistent with autophagy activation, whereas a mutant lacking LLO was not. Bacillus subtilis expressing either LLO or a related cytolysin, perfringolysin O (PFO), induced LC3 colocalization and LC3 lipidation. Further, LLO-containing liposomes also recruited LC3-GFP, indicating that LLO was sufficient to induce targeted autophagy in the absence of infection. The role of autophagy had variable effects depending on the cell type assayed. In atg5^−/− mouse embryonic fibroblasts, L. monocytogenes had a primary vacuole escape defect. However, the bacteria escaped and grew normally in atg5^−/− BMDMs.

Conclusions/Significance

We propose that membrane damage, such as that caused by LLO, triggers bacterial-targeted autophagy, although autophagy does not affect the fate of wild-type intracellular L. monocytogenes in primary BMDMs.     

Prevention of allograft tolerance by bacterial infection with Listeria monocytogenes

Exposure to certain viruses and parasites has been shown to prevent the induction of transplantation tolerance in mice via the generation of cross-reactive memory T cell responses or the induction of bystander activation. Bacterial infections are common in the perioperative period of solid organ allograft recipients in the clinic, and correlations between bacterial infections and acute allograft rejection have been reported. However, whether bacterial infections at the time of transplantation have any effect on the generation of transplantation tolerance remains to be established. We used the Gram-positive intracellular bacterium Listeria monocytogenes (LM) as a model pathogen because its effects on immune responses are well described. Perioperative LM infection prevented cardiac and skin allograft acceptance induced by anti-CD154 and donor-specific transfusion in mice. LM-mediated rejection was not due to the generation of cross-reactive T cells and was largely independent of signaling via MyD88, an adaptor for most TLRs, IL-1, and IL-18. Instead, transplant rejection following LM infection was dependent on the expression of the phagosome-lysing pore former listeriolysin O and on type I IFN receptor signaling. Our results indicate that bacterial exposure at the time of transplantation can antagonize tolerogenic regimens by enhancing alloantigen-specific immune responses independently of the generation of cross-reactive memory T cells.     

Actin and phosphoinositide binding by the ActA protein of the bacterial pathogen Listeria monocytogenes

The surface protein ActA of the pathogenic bacterium Listeria monocytogenes induces actin-driven movement of bacteria in the cytoplasm of infected host cells and serves as a model for actin-based motility in general. We generated and purified soluble recombinant fragments of ActA and assessed their ability to interact with the acidic phospholipids phosphatidylinositol 4,5-bisphosphate and phosphatidylinositol 3,4,5-trisphosphate, both implicated in the regulation of actin polymerization. Purified ActA consisted of biologically active, elongated molecules with an alpha-helix and beta-sheet content of 11 and 32%, respectively. In the presence of either phosphatidylinositol 4,5-bisphosphate or phosphatidylinositol 3,4,5-trisphosphate, but not phosphatidylcholine, ActA molecules underwent a structural change that raised the alpha-helix content to 19% and lowered the beta-sheet content to 27%. Co-sedimentation experiments with phosphatidylcholine vesicles containing different acidic phospholipids demonstrated that ActA binds preferentially to D-3 phosphoinositides. The D-3 phosphoinositide binding activity was mapped to a small subregion in the N-terminal domain of ActA. This subregion comprised 19 amino acids and showed homology to cecropins. In addition, we found that amino acids 33 to 74 of ActA mediated actin binding by the whole, folded ActA molecule. These findings shed new light on ActA function.     

Listeria monocytogenes antagonizes the human GTPase Cdc42 to promote bacterial spread

The bacterial pathogen Listeria monocytogenes uses actin‐based motility to spread from infected human cells to surrounding healthy cells. Cell–cell spread involves the formation of thin extensions of the host plasma membrane (‘protrusions’) containing motile bacteria. In cultured enterocytes, the Listeria protein InlC promotes protrusion formation by binding and antagonizing the human scaffolding protein Tuba. Tuba is a known activator of the GTPase Cdc42. In this work, we demonstrate an important role for Cdc42 in controlling Listeria spread. Infection of the enterocyte cell line Caco‐2 BBE1 induced a decrease in the level of Cdc42‐GTP, indicating that Listeria downregulates this GTPase. Genetic data involving RNA interference indicated that bacterial impairment of Cdc42 may involve inhibition of Tuba. Experiments with dominant negative and constitutively activated alleles of Cdc42 demonstrated that the ability to inactivate Cdc42 is required for efficient protrusion formation by Listeria. Taken together, these findings indicate a novel mechanism of bacterial spread involving pathogen‐induced downregulation of host Cdc42.     

Biodiversity of the species Listeria monocytogenes and the genus Listeria

This review describes the Listeria monocytogenes genome sequences available today and their comparison with that of Listeria innocua and Listeria welshimeri by highlighting their characteristic features and common traits. The diversity present among them is analysed with emphasis on putative virulence and host-pathogen interaction related functions. Then large-scale studies comparing gene content of Listeria and how these studies contributed to typing applications will be discussed. Finally, evolutionary conclusions and future perspectives in Listeria genomics are presented.     

Detection and quantification of Listeria monocytogenes by 5'-nuclease polymerase chain reaction targeting the actA gene

AIMS: The aim of this study was to develop a 5'-nuclease polymerase chain reaction (PCR) for the rapid detection and quantification of Listeria monocytogenes. METHODS AND RESULTS: Specific primers and a fluorogenic probe were designed, which target a specific sequence of the actA gene encoding for a protein involved in the actin filament assembly. The PCR system was highly sensitive and specific for L. monocytogenes (inclusivity, 100%; exclusivity, 100%), which was determined using 46 L. monocytogenes and 28 non-L. monocytogenes strains. Detection limits of 10(4) cfu ml(-1) after 35 cycles and 10(2) cfu ml(-1) after 45 cycles were achieved by PCR in both real-time and end-point fluorescence measurement modes. Linear calibration lines were obtained in the range from 10(2) to 10(9) cfu ml(-1) for three L. monocytogenes strains in real-time PCR with 45 cycles. CONCLUSIONS: The developed 5'-nuclease PCR of the actA gene provides a new target for the rapid detection and quantification of L. monocytogenes. SIGNIFICANCE AND IMPACT OF THE STUDY: In conjunction with enrichment or with an appropriate quantitative sample preparation technique, the method is suitable for food safety applications.     

Autolysis of Listeria monocytogenes

Physiological conditions that could provide maximal rates of autolysis of Listeria monocytogenes were examined. L. monocytogenes was found to be refractory to most treatments that promote rapid autolysis in other bacteria. Best rates of autolysis were obtained after resuspending the cells in Tris-hydrochloride buffer at 37 degrees C with the pH optimum at 8.0. Autolysis was also efficiently promoted by the surfactant Triton X-100. Antibiotics that interfere with the biosynthesis of the cell wall murein (peptidoglycan) caused death of the cells without autolysis after prolonged incubation in the presence of the drug. Only nisin, which has been shown to bind in vitro to the murein precursors lipid I and lipid II brings about autolysis of L. monocytogenes cells, although with slower kinetics than in the case of Tris-HCl and Triton.     

Autolysis of Listeria monocytogenes

Autolytic curves of five representative strains of Listeria monocytogenes are described. Of 24 strains so far examined, the majority are unstable in vitro.     

Minimum growth temperatures of Listeria monocytogenes and non-haemolytic Listeria

Minimum growth temperatures and those of decreased growth were determined for 100 strains of listerias. The ability of 78 strains of Listeria monocytogenes isolated from animals and 22 non-haemolytic strains to grow at low temperatures was studied, using a flooding technique, in a plate-type continuous temperature gradient incubator at temperatures between -1.6 and 14.5 degrees C. The mean minimum temperature for L. monocytogenes was +1.7 +/- 0.5 degrees C. The growth of non-haemolytic listerias was unobservable at +1.7 +/- 0.5 degrees C. The L. monocytogenes strains grew at about 0.6 degrees C lower than the non-pathogenic strains. No differences in growth temperatures were observed among L. monocytogenes strains isolated from different sources. The serovars with the OI antigen grew at lower temperatures (+1.0 +/- 0.3 degrees C) than the other common serovar 4b (+1.3 +/- 0.4 degrees C). The results indicate that L. monocytogenes grows better than non-haemolytic strains under cold conditions. The possible role of haemolysins as growth factors is also discussed.