Shigella and autophagy

Bacterial invasion of eukaryotic cells, and host recognition and elimination of the invading bacteria, determines the fate of bacterial infection. Once inside mammalian cells, many pathogenic bacteria enter the host cytosol to escape from the lytic compartment and gain a replicative niche. Recent studies indicate that autophagy also recognizes intracellular bacteria. Although autophagy is a conserved membrane trafficking pathway in eukaryotic cells that sequesters undesirable or recyclable cytoplasmic components or organelles and delivers them to lysosomes, autophagy has recently been described as playing a pivotal role as an intracellular surveillance system for recognition and eradication of the pathogens that have invaded the cytoplasm. Indeed, unless they are able to circumvent entrapping by autophagosomes, bacteria ultimately undergo degradation by delivery into autolysosomes. In this review we discuss recent discoveries regarding Shigella strategies for infecting mammalian cells, and then focus on recent studies of an elegant bacterial survival strategy against autophagic degradation.     

Intracellular survival of Shigella

Bacterial invasion of eukaryotic cells and host recognition and killing of the invading bacteria are a key issue in determining the fate of bacterial infection. Once inside host cells, pathogenic bacteria often modify the phagosomal compartment or enter the host cytosol to escape from the lytic compartment and gain a replicative niche. Cytosolic invaders, however, are monitored by host innate immune systems, such as mediated by Nod/CARD family proteins, which induce inflammatory responses via activation of NF-kappaB. Furthermore, recent studies indicate that autophagy, a major cytoplasmic degradation system that eliminates cytosolic protein and organelles, also recognizes invading bacteria. Indeed, unless they are able to circumvent entrapping by autophagic membranes, bacteria targeted by autophagy ultimately undergo degradation by delivery into autolysosomes. In this article, we review recent advances in understanding of Shigella strategies to infect epithelial cells, and then focus on recent studies of an intriguing bacterial survival strategy against autophagic degradation.     

Type III secretion effectors of the IpaH family are E3 ubiquitin ligases

Many bacteria pathogenic for plants or animals, including Shigella spp., which is responsible for shigellosis in humans, use a type III secretion apparatus to inject effector proteins into host cells. Effectors alter cell signaling and host responses induced upon infection; however, their precise biochemical activities have been elucidated in very few cases. Utilizing Saccharomyces cerevisiae as a surrogate host, we show that the Shigella effector IpaH9.8 interrupts pheromone response signaling by promoting the proteasome-dependent destruction of the MAPKK Ste7. In vitro, IpaH9.8 displayed ubiquitin ligase activity toward ubiquitin and Ste7. Replacement of a Cys residue that is invariant among IpaH homologs of plant and animal pathogens abolished the ubiquitin ligase activity of IpaH9.8. We also present evidence that the IpaH homolog SspH1 from Salmonella enterica can ubiquitinate ubiquitin and PKN1, a previously identified SspH1 interaction partner. This study assigns a function for IpaH family members as E3 ubiquitin ligases.     

Iron and virulence in Shigella

Iron limitation, a condition encountered within mammalian hosts, induces the synthesis of a number of proteins in pathogenic Shigella species. These include several outer membrane proteins, Shiga toxin, and proteins involved in the biosynthesis and transport of high-affinity iron-binding compounds or siderophores. Although siderophores have been shown to play a major role in the virulence of some bacterial pathogens, these compounds do not appear to be essential for the virulence of Shigella species. Unlike those pathogens which are restricted to the extracellular compartments of the host, the Shigella species invade and multiply within host cells. Alternative iron-acquisition systems, such as the ability to utilize haem-iron, permit growth of the intracellular bacteria. Virulent shigellae also possess a cell-surface haem-binding protein, and synthesis of this protein correlates with infectivity and virulence. This protein does not appear to be involved in iron acquisition. Rather, it may allow the bacteria to coat themselves with haem compounds, thus enhancing their ability to interact with target host cells.     

How to dodge pyroptosis:lessons from Shigella flexneri

Bacillary dysentery is an intestinal infection caused by Shigella,a group of Gram-negative bacteria that roam freely in the cytosol of infected host cells.     

病原细菌效应蛋白靶向宿主细胞核研究进展*

细胞核是细胞遗传与代谢的控制中心,调控细胞对外界的响应、代谢、生长和分化等细胞活动。在细菌感染宿主细胞过程中,个别细菌来源的效应蛋白能够靶向进入宿主细胞核,影响细胞核内基因的转录、RNA剪切、DNA修复以及染色质重组等生命活动,将这些能够进入细胞核的细菌效应蛋白称之为核调节蛋白。对病原菌分泌的核调节蛋白进入宿主细胞核的方式,以及不同病原菌的核调节蛋白调控宿主细胞的生命过程进行归纳总结,从而为深入探究病原细菌感染宿主细胞的致病机理提供理论基础。     

Shigella protein IpaH(9.8) is secreted from bacteria within mammalian cells and transported to the nucleus.

Various pathogenic bacteria such as Shigella deliver effector proteins into mammalian cells via the type III secretion system. The delivered Shigella effectors have been shown to variously affect host functions required for efficient bacterial internalization into the cells. In the present study, we investigated the IpaH proteins for their ability to be secreted via the type III secretion system and their fate in mammalian cells. Upon incubation in a medium containing Congo red, the bacteria secrete IpaH into the medium, but secretion of IpaH occurs later than that of IpaBCD. Immunofluorescence microscopy indicated that IpaH(9.8) is secreted from intracellular bacteria and transported into the nucleus. On microinjection of the protein, intracellular IpaH(9.8) is accumulated at one place around the nucleus and transported into the nucleus. This movement seems to be dependent on the microtubule network, since nuclear accumulation of IpaH(9.8) is inhibited in cells treated with microtubule-destabilizing agents. In nuclear import assay, IpaH(9.8) was efficiently transported into the nucleus, which was completely blocked by treatment with wheat germ agglutinin. The nuclear transport of IpaH(9.8) does not depend on host cytosolic factors but is partially dependent on ATP/GTP, suggesting that, like beta-catenin, IpaH(9.8) secreted from intracellular Shigella can be transported into the nucleus.     

Entrapment of intracytosolic bacteria by septin cage-like structures

Actin-based motility is used by various pathogens for dissemination within and between cells. Yet host factors restricting this process have not been identified. Septins are GTP-binding proteins that assemble as filaments and are essential for cell division. However, their role during interphase has remained elusive. Here, we report that septin assemblies are recruited to different bacteria that polymerize actin. We observed that intracytosolic Shigella either become compartmentalized in septin cage-like structures or form actin tails. Inactivation of septin caging increases the number of Shigella with actin tails and enhances cell-to-cell spread. TNF-α, a host cytokine produced upon Shigella infection, stimulates septin caging and restricts actin tail formation and cell-to-cell spread. Finally, we show that septin cages entrap bacteria targeted to autophagy. Together, these results reveal an unsuspected mechanism of host defense that restricts dissemination of invasive pathogens.     

IpaD is localized at the tip of the Shigella flexneri type III secretion apparatus

Type III secretion (T3S) systems are used by numerous Gram-negative pathogenic bacteria to inject virulence proteins into animal and plant host cells. The core of the T3S apparatus, known as the needle complex, is composed of a basal body transversing both bacterial membranes and a needle protruding above the bacterial surface. In Shigella flexneri, IpaD is required to inhibit the activity of the T3S apparatus prior to contact of bacteria with host and has been proposed to assist translocation of bacterial proteins into host cells. We investigated the localization of IpaD by electron microscopy analysis of cross-linked bacteria and mildly purified needle complexes. This analysis revealed the presence of a distinct density at the needle tip. A combination of single particle analysis, immuno-labeling and biochemical analysis, demonstrated that IpaD forms part of the structure at the needle tip. Anti-IpaD antibodies were shown to block entry of bacteria into epithelial cells.     

IpaD is localized at the tip of the Shigella flexneri type III secretion apparatus

Type III secretion (T3S) systems are used by numerous Gram-negative pathogenic bacteria to inject virulence proteins into animal and plant host cells. The core of the T3S apparatus, known as the needle complex, is composed of a basal body transversing both bacterial membranes and a needle protruding above the bacterial surface. In Shigella flexneri, IpaD is required to inhibit the activity of the T3S apparatus prior to contact of bacteria with host and has been proposed to assist translocation of bacterial proteins into host cells. We investigated the localization of IpaD by electron microscopy analysis of cross-linked bacteria and mildly purified needle complexes. This analysis revealed the presence of a distinct density at the needle tip. A combination of single particle analysis, immuno-labeling and biochemical analysis, demonstrated that IpaD forms part of the structure at the needle tip. Anti-IpaD antibodies were shown to block entry of bacteria into epithelial cells.     

Intravenous infection of virulent shigellae causes fulminant hepatitis in mice

Shigella spp. are pathogenic bacteria responsible for bacillary dysentery in humans. The major lesions in colonic mucosa are intense inflammation with apoptosis of macrophages and release of pro-inflammatory cytokines. The study of shigellosis is hindered by the natural resistance of rodents to oral infection with Shigella. Therefore, animal models exploit other routes of infection. Here, we describe a novel murine model in which animals receive shigellae via the caudal vein. Mice infected with 5 x 10(6) (LD(50)) virulent shigellae died at 48 h post infection, whereas animals receiving non-invasive mutants survived. The liver is the main target of infection, where shigellae induce microgranuloma formation. In mice infected with invasive bacteria, high frequency of apoptotic cells is observed within hepatic microgranulomas along with significant levels of mRNA for pro-inflammatory cytokines such as IL-1beta, IL-18, IL-12 and IFN-gamma. Moreover, in the blood of these animals high levels of IL-6 and transaminases are detected. Our results demonstrate the intravenous model is suitable for pathogenicity studies and useful to explore the immune response after Shigella infection.     

Autophagy and the cytoskeleton: new links revealed by intracellular pathogens

Actin-based motility is used by various pathogens such as Listeria and Shigella for dissemination within cells: and tissues, yet host factors counteracting this process have not been identified. We have recently discovered that infected host cells can prevent actin-based motility of Shigella by compartmentalizing bacteria inside 'septin cages,' revealing a novel mechanism of host defense that restricts dissemination. Because bacterial proteins controlling actin-based motility also regulate the autophagy process, we hypothesized and then established a link between septin caging and autophagy. Together, these results unveiled the first cellular mechanism that counteracts pathogen dissemination. Understanding the role of septins, a so far poorly characterized component of the cytoskeleton, will thus provide new insights into bacterial infection and autophagy.     

No effect of Wolbachia on resistance to intracellular infection by pathogenic bacteria in Drosophila melanogaster

Multiple studies have shown that infection with the endosymbiotic bacterium Wolbachia pipientis confers Drosophila melanogaster and other insects with resistance to infection by RNA viruses. Studies investigating whether Wolbachia infection induces the immune system or confers protection against secondary bacterial infection have not shown any effect. These studies, however, have emphasized resistance against extracellular pathogens. Since Wolbachia lives inside the host cell, we hypothesized that Wolbachia might confer resistance to pathogens that establish infection by invading host cells. We therefore tested whether Wolbachia-infected D. melanogaster are protected against infection by the intracellular pathogenic bacteria Listeria monocytogenes and Salmonella typhimurium, as well as the extracellular pathogenic bacterium Providencia rettgeri. We evaluated the ability of flies infected with Wolbachia to suppress secondary infection by pathogenic bacteria relative to genetically matched controls that had been cured of Wolbachia by treatment with tetracycline. We found no evidence that Wolbachia alters host ability to suppress proliferation of any of the three pathogenic bacteria. Our results indicate that Wolbachia-induced antiviral protection does not result from a generalized response to intracellular pathogens.     

Membrane rafts: a potential gateway for bacterial entry into host cells

Pathogenic bacteria have developed various mechanisms to evade host immune defense systems. Invasion of pathogenic bacteria requires interaction of the pathogen with host receptors, followed by activation of signal transduction pathways and rearrangement of the cytoskeleton to facilitate bacterial entry. Numerous bacteria exploit specialized plasma membrane microdomains, commonly called membrane rafts, which are rich in cholesterol, sphingolipids and a special set of signaling molecules which allow entry to host cells and establishment of a protected niche within the host. This review focuses on the current understanding of the raft hypothesis and the means by which pathogenic bacteria subvert membrane microdomains to promote infection.     

Bacteria-infected fibroblasts have enhanced susceptibility to the cytotoxic action of tumor necrosis factor.

The susceptibility of bacteria-infected fibroblasts to the cytotoxic action of tumor necrosis factor was investigated. L cells infected with Shigella flexneri, Salmonella typhimurium, or Listeria monocytogenes, had an enhanced susceptibility to the cytotoxic activity of TNF-alpha. This enhanced susceptibility was dependent upon the challenge dose of bacteria, the concentration of TNF, and upon the exposure time of bacteria-infected cells to TNF. L cells infected with S. flexneri were susceptible to the cytotoxic action of TNF at 2 to 6 h after bacterial infection. In contrast, L cells infected with S. typhimurium or L. monocytogenes did not show enhanced susceptibility to TNF until 14 h postbacterial infection and exposure to TNF. Enhanced susceptibility to TNF was dependent on bacterial invasion because fibroblasts pretreated with a noninvasive isogenic variant of S. flexneri, UV-treated invasive bacteria, bacterial cultural supernatant, or bacteria LPS were no more susceptible to TNF than untreated cells. Enhanced susceptibility to TNF by bacteria-infected cells was not unique to L cells. Mouse embryo fibroblasts and HeLa cells also showed similar reactivities after bacteria infection. Bacteria-infected cells were greatly suppressed in host cell protein synthesis that may play an important role in their enhanced susceptibility to TNF. These results suggest that an important role of TNF in host defense against bacterial infections is its cytotoxic activity against bacteria-infected cells.     

胞内致病菌入侵宿主细胞分子机理研究进展

胞内致病菌,指能够侵入宿主细胞且在宿主细胞内存活并繁殖的病原菌。其入侵宿主细胞的过程主要涉及细菌黏附宿主细胞、侵袭、细菌在细胞内存活以及引起宿主细胞损伤等。先前的研究表明大多数胞内致病菌是通过吞噬细胞被动地摄取,而随着分子生物学和免疫学的发展,越来越多的胞内致病菌被证明能主动入侵到宿主细胞体内,并进化出各种调控宿主细胞信号通路的方式。本文讨论了胞内致病菌在入侵宿主细胞时各阶段的共同的分子机制以及常见的胞内致病菌所采取的入侵策略,并对近年来国内外主要相关研究进展做一总结。     

Shigella effector IpaH9.8 binds to a splicing factor U2AF(35) to modulate host immune responses

Shigella effectors injected into the host cell via the type III secretion system are involved in various aspects of infection. Here, we show that one of the effectors, IpaH9.8, plays a role in modulating inflammatory responses to Shigella infection. In murine lung infection model, DeltaipaH9.8 mutant caused more severe inflammatory responses with increased pro-inflammatory cytokine production levels than did wild-type Shigella, which resulted in a 30-fold decrease in bacterial colonization. Binding assays revealed that IpaH9.8 has a specific affinity to U2AF(35), a mammalian splicing factor, which interferes with U2AF(35)-dependent splicing as assayed for IgM pre-mRNA. Reducing the U2AF(35) level in HeLa cells and infecting HeLa cells with wild-type caused a decrease in the expression of the il-8, RANTES, GM-CSF, and il-1beta genes as examined by RT-PCR. The results indicate that IpaH9.8 plays a role in Shigella infection to optimize the host inflammatory responses, thus facilitating bacterial colonization within the host epithelial cells.     

The impact of iron on Listeria monocytogenes; inside and outside the host

As iron is vital for all cells, host sequestration of iron provides a significant barrier to bacterial infection. The absolute requirement for iron has driven the evolution of refined systems by which pathogenic bacteria such as Listeria monocytogenes can competitively acquire this element during host infection. This process is coordinated, at least partly, by the Ferric Uptake Regulator (Fur). Recent studies have identified loci within the listerial Fur-regulon and have characterized specific systems involved in iron uptake from various sources. This work has greatly advanced our knowledge of the mechanisms underpinning iron homeostasis in L. monocytogenes. A greater understanding of the molecular mechanisms by which pathogenic bacteria acquire iron is significant from both a food safety and public-health perspective.