Stimulation of autophagy suppresses the intracellular survival of Burkholderia pseudomallei in mammalian cell lines

Burkholderia pseudomallei is the causative agent of melioidosis, a tropical infection of humans and other animals. The bacterium is an intracellular pathogen that can escape from endosomes into the host cytoplasm, where it replicates and infects adjacent cells. We investigated the role played by autophagy in the intracellular survival of B. pseudomallei in phagocytic and non-phagocytic cell lines. Autophagy was induced in response to B. pseudomallei invasion of murine macrophage (RAW 264.7) cells and a proportion of the bacteria co-localized with the autophagy effector protein LC3, a marker for autophagosome formation. Pharmacological stimulation of autophagy in RAW 264.7 and murine embryonic fibroblast (MEF) cell lines resulted in increased co-localization of B. pseudomallei with LC3 while basal levels of co-localization could be abrogated using inhibitors of the autophagic pathway. Furthermore, induction of autophagy decreased the intracellular survival of B. pseudomallei in these cell lines, but bacterial survival was not affected in MEF cell lines deficient in autophagy. Treatment of infected macrophages with chloramphenicol increased the proportion of bacteria within autophagosomes indicating that autophagic evasion is an active process relying on bacterial protein synthesis. Consistent with this hypothesis, we identified a B. pseudomallei type III secreted protein, BopA, which plays a role in mediating bacterial evasion of autophagy. We conclude that the autophagic pathway is a component of the innate defense system against invading B. pseudomallei, but which the bacteria can actively evade. However, when autophagy is pharmacologically induced using rapamycin, bacteria are actively sequestered in autophagosomes, ultimately decreasing their survival.     

An Inv/Mxi-Spa-like type III protein secretion system in Burkholderia pseudomallei modulates intracellular behaviour of the pathogen

Burkholderia pseudomallei is the causative agent of melioidosis, a serious infectious disease of humans and animals that is endemic in subtropical areas. B. pseudomallei is a facultative intracellular pathogen that may invade and survive within eukaryotic cells for prolonged periods. After internalization, the bacteria escape from endocytic vacuoles into the cytoplasm of infected cells and form membrane protrusions by inducing actin polymerization at one pole. It is believed that survival within phagocytic cells and cell-to-cell spread via actin protrusions is required for full virulence. We have studied the role of a putative type III protein secretion apparatus (Bsa) in the interaction between B. pseudomallei and host cells. The Bsa system is very similar to the Inv/Mxi-Spa type III secretion systems of Salmonella and Shigella. Moreover, B. pseudomallei encodes proteins that are very similar to Salmonella and Shigella Inv/Mxi-Spa secreted proteins required for invasion, escape from endocytic vacuoles, intercellular spread and pathogenesis. Antibodies to putative Bsa-secreted proteins were detected in convalescent serum from a melioidosis patient, suggesting that the system is functionally expressed in vivo. B. pseudomallei mutant strains lacking components of the Bsa secretion and translocation apparatus were constructed. The mutant strains exhibited reduced replication in J774.2 murine macrophage-like cells, an inability to escape from endocytic vacuoles and a complete absence of formation of membrane protrusions and actin tails. These findings indicate that the Bsa type III secretion system plays an essential role in modulating the intracellular behaviour of B. pseudomallei.     

Dexamethasone Modulation of the Interaction between Two Types of Phagocytes of the Holothurian <Emphasis Type="Italic">Eupentacta fraudatrix</Emphasis> (Djakonov et Baranova, 1958) (Holothuroidea: Dendrochirotida)

This study examines the interaction between two types of phagocytes (P1 and P2) of the holothurian Eupentacta fraudatrix and its in vitro modulation by dexamethasone. Our results indicate that inhibition of apoptosis in P1 phagocytes by P2 phagocytes was accompanied by increased activities of antioxidant enzymes and reduced synthesis of interleukin-1α-like substances. We hypothesize that P1-phagocyte-related effects occurred in response to a high level of hydrogen peroxide produced by P2 phagocytes. The reduced anti-apoptotic effect of P2-phagocyte supernatant during prolonged incubation (24 h) was accompanied by a decline in defense reactions in P1 phagocytes due to depletion of antioxidant enzymes (catalase, glutathione reductase, and glutathione transferase). Inhibition of apoptotis in P1 phagocytes associated with upregulation of antioxidant enzyme defense in response to P2 phagocytes preincubated with dexamethasone (100 µM) indicates that P2 phagocytes affect P1 phagocytes via a ROS-associated mechanism. Thus, our data provide evidence that P1 and P2 phagocytes exhibit their maximum activity at different stages of the immune response, thus causing inhibition of activity in target cells during prolonged exposure. Dexamethasone enhances these effects.     

Endotoxin of Pseudomonas pseudomallei detected by the body weight-decreasing reaction in mice and comparison of it with those of P. cepacia and P. aeruginosa.

The heat-treated whole cells, culture supernatants, and extracted endotoxin preparations of Pseudomonas pseudomallei were examined for endotoxin by the mouse body weight-decreasing (BWD) test. The experiments were conducted also with those of P. cepacia and P aeruginosa. Endotoxin was detected in all the samples of P. pseudomallei. Endotoxin of P. cepacia was detected in whole cells, but not in culture supernatant. The BWD activity of P. aeruginosa was 30 times as high as that of P. pseudomallei. This result was confirmed by the experiments with endotoxin preparations. In the limulus amebocyte lysate gelation (LAL) test, however, the endotoxin preparations of the two species showed the same level of activity.     

Burkholderia pseudomallei interferes with inducible nitric oxide synthase (iNOS) production: a possible mechanism of evading macrophage killing

Burkholderia pseudomallei is a causative agent of melioidosis, a life threatening disease which affects humans and animals in tropical and subtropical areas. This bacterium is known to survive and multiply inside cells such as macrophages. The mechanism of host defense against this bacterium is still unknown. In this study, we demonstrated that B. pseudomallei exhibited unique macrophage activation activity compared with Escherichia coli and Salmonella typhi. The mouse macrophage cell line (RAW 264.7) infected with B. pseudomallei at MOI of 0.1:1, 1:1 and 10:1 did not express a detectable level of inducible nitric oxide synthase (iNOS). Moreover, the B. pseudomallei infected cells released TNF-alpha only when they were infected with high MOI (10:1). Unlike the cells infected with B. pseudomallei, the cells infected with E. coli, and S. typhi expressed iNOS even at MOI of 0.1:1. These infected cells also released a significantly higher level of TNF-alpha at the low MOI ratio. The cells that were preactivated with IFN-gamma prior to being infected with B. pseudomallei exhibited an enhanced production of iNOS and TNF-alpha release. The increased macrophage activation activity in the presence of IFN-gamma also correlated with the restriction of the intracellular bacteria survival. Moreover, IFN-gamma also prevented cell fusion and multinucleated cell formation induced by B. pseudomallei, a phenomenon recently described by our group. Altogether, these results indicate that internalization of B. pseudomallei failed to trigger substantial macrophage activation, a phenomenon which could prolong their survival inside the phagocytic cells and facilitate a direct cell to cell spreading of B. pseudomallei to neighboring cells.     

Effects of Burkholderia pseudomallei and other Burkholderia species on eukaryotic cells in tissue culture

Burkholderia pseudomallei causes melioidosis, a serious and often fatal bacterial infection. B. pseudomallei can behave as a facultatively intracellular organism and this ability may be important in the pathogenesis of both acute and chronic infection. The uptake of B. pseudomallei and other Burkholderia spp. by cells in tissue culture was examined by electron microscopy. B. pseudomallei can invade cultured cell lines including phagocytic lines such as RAW264, J774 and U937, and non-phagocytic lines such as CaCO-2, Hep2, HeLa, L929, McCoy, Vero and CHO. Uptake was followed by the intracellular multiplication of B. pseudomallei and the induction of cell fusion and multinucleate giant cell formation. Similar effects were produced by B. mallei and B. thailandensis.     

Dexamethasone treatment in vitro resulted in different responses of two fractions of phagocytes of the holothurian Eupentacta fraudatrix

Echinoderm phagocytes are considered to be analogues to vertebrate macrophages. Previously, the phagocytes of some echinoderm species were divided into two fractions with unclearly identified functional properties. This study aims at modeling the immune response of two phagocyte fractions (P1 and P2) of the holothurian Eupentacta fraudatrix to the synthetic glucocorticoid hormone dexamethasone (Dex) in vitro and at comparison of the effects of such pretreatment on humoral cooperation of each phagocyte fraction with another type of immunocytes, morula cells. During 48-h incubation, Dex (0.1–100 μM) induced apoptosis in a direct (in the P1 fraction) or reverse (in the P2 fraction) concentration-dependent manner. In addition, 100 μM Dex differently affected the cytokin-like substance level in the P1 and P2 phagocyte fractions. Moreover, the supernatants of the Dex(100 μM)-pretreated phagocytes induced opposite changes in the IL-1-like substance level in morula cells. These results indicate a striking functional difference between the two phagocyte fractions. The data obtained provide a new insight into the evolution of macrophage response and into the prospects of the use of in vitro holothurian phagocyte model.     

The ultrastructural characteristics of the causative agent of melioidosis and its interaction with phagocytes in vivo

The electron microscopic studies have established that the virulent strain of Pseudomonas pseudomallei C-141, an agent of melioidosis, being intraperitoneally administered to guinea pigs, forms in vivo three morphological variants. One variant is capsule-free, while two others have a capsule which in the second variant may be referred by its characters to the microcapsule and in the third one to the macrocapsule. It has been shown that under the interaction of these three morphological variants with the microorganism cells the bacteria of the first and second variants are absorbed by phagocytes, whereas the microbial cells of the third morphological variant are more resistant to the phagocytosis.     

Actin-based motility of Burkholderia pseudomallei involves the Arp 2/3 complex,but not N-WASP and Ena/VASP proteins

The facultative intracellular bacterium Burkholderia pseudomallei induces actin rearrangement within infected host cells leading to formation of actin tails and membrane protrusions. To investigate the underlying mechanism we analysed the contribution of cytoskeletal proteins to B. pseudomallei-induced actin tail assembly. By using green fluorescent protein (GFP)-fusion constructs, the recruitment of the Arp2/3 complex, vasodilator-stimulated phosphoprotein (VASP), Neural Wiskott-Aldrich syndrome protein (N-WASP), zyxin, vinculin, paxillin and alpha-actinin to the surface of B. pseudomallei and into corresponding actin tails was studied. In addition, antibodies against the same panel of proteins were used for immunolocalization. Whereas the Arp2/3 complex and alpha-actinin were incorporated into B. pseudomallei-induced actin tails, none of the other proteins were detected in these structures. The overexpression of an Arp2/3 binding fragment of the Scar1 protein, shown previously to block actin-based motility of Listeria, had no effect on B. pseudomallei tail formation. Infections of either N-WASP- or Ena/VASP-defective cells showed that these proteins are not essential for B. pseudomallei-induced actin polymerization. In conclusion, our results suggest that B. pseudomallei induces actin polymerization through a mechanism that differs from those evolved by Listeria, Shigella, Rickettsia or vaccinia virus.     

Bystander activation of CD8+ T cells contributes to the rapid production of IFN-gamma in response to bacterial pathogens

The bacterium Burkholderia pseudomallei causes a life-threatening disease called melioidosis. In vivo experiments in mice have identified that a rapid IFN-gamma response is essential for host survival. To identify the cellular sources of IFN-gamma, spleen cells from uninfected mice were stimulated with B. pseudomallei in vitro and assayed by ELISA and flow cytometry. Costaining for intracellular IFN-gamma vs cell surface markers demonstrated that NK cells and, more surprisingly, CD8(+) T cells were the dominant sources of IFN-gamma. IFN-gamma(+) NK cells were detectable after 5 h and IFN-gamma(+) CD8(+) T cells within 15 h after addition of bacteria. IFN-gamma production by both cell populations was inhibited by coincubation with neutralizing mAb to IL-12 or IL-18, while a mAb to TNF had much less effect. Three-color flow cytometry showed that IFN-gamma-producing CD8(+) T cells were of the CD44(high) phenotype. The preferential activation of NK cells and CD8(+) T cells, rather than CD4(+) T cells, was also observed in response to Listeria monocytogenes or a combination of IL-12 and IL-18 both in vitro and in vivo. This rapid mechanism of CD8(+) T cell activation may be an important component of innate immunity to intracellular pathogens.     

Impact of streptozotocin-induced diabetes on functional responses of dendritic cells and macrophages towards Burkholderia pseudomallei

Diabetes mellitus is a documented risk factor for melioidosis, a tropical infection caused by Burkholderia pseudomallei. The increased susceptibility of diabetic individuals to infections with other pathogens has been associated with immune dysregulation. However, the impact of diabetes on the functional responses of dendritic cells (DC) and macrophages during B. pseudomallei infection has not been investigated. This study compared the responses of macrophages and DC towards B. pseudomallei using bone marrow-derived DC (BMDC) and peritoneal elicited macrophages (PEM) isolated from streptozotocin-induced diabetic C57BL/6 mice exhibiting hyperglycaemia for 9 days (acute) or 70 days (chronic) and age-matched nondiabetic C57BL/6 mice. Following coincubation of BMDC and PEM with a highly virulent B. pseudomallei isolate, maturation, bacterial internalization plus intracellular survival and cytokine gene expression profiles were assessed. No significant differences in functional responses of BMDC or PEM isolated from acute diabetic and nondiabetic mice were observed. However, significant differences in BMDC and PEM function were observed when chronic diabetic and nondiabetic mice were compared. This study demonstrates that diabetic mice with extended periods of uncontrolled hyperglycaemia have impaired DC and macrophage function towards B. pseudomallei, which may contribute to the high susceptibility observed in clinical practice.     

The Burkholderia pseudomallei type III secretion system and BopA are required for evasion of LC3-associated phagocytosis

Burkholderia pseudomallei is the causative agent of melioidosis, a fatal infectious disease endemic in tropical regions worldwide, and especially prevalent in southeast Asia and northern Australia. This intracellular pathogen can escape from phagosomes into the host cytoplasm, where it replicates and infects adjacent cells. We previously demonstrated that, in response to B. pseudomallei infection of macrophage cell line RAW 264.7, a subset of bacteria co-localized with the autophagy marker protein, microtubule-associated protein light chain 3 (LC3), implicating autophagy in host cell defence against infection. Recent reports have suggested that LC3 can be recruited to both phagosomes and autophagosomes, thereby raising questions regarding the identity of the LC3-positive compartments in which invading bacteria reside and the mechanism of the autophagic response to B. pseudomallei infection. Electron microscopy analysis of infected cells demonstrated that the invading bacteria were either free in the cytosol, or sequestered in single-membrane phagosomes rather than double-membrane autophagosomes, suggesting that LC3 is recruited to B. pseudomallei-containing phagosomes. Partial or complete loss of function of type III secretion system cluster 3 (TTSS3) in mutants lacking the BopA (effector) or BipD (translocator) proteins respectively, resulted in delayed or no escape from phagosomes. Consistent with these observations, bopA and bipD mutants both showed a higher level of co-localization with LC3 and the lysosomal marker LAMP1, and impaired survival in RAW264.7 cells, suggesting enhanced killing in phagolysosomes. We conclude that LC3 recruitment to phagosomes stimulates killing of B. pseudomallei trapped in phagosomes. Furthermore, BopA plays an important role in efficient escape of B. pseudomallei from phagosomes.     

Antigenic properties of the electrophoretic fractions of the causative agent of melioidosis

Antisera to the antigens of 5 fractions, isolated as the result of the separation of P. pseudomallei aqueous saline extract by continuous electrophoresis in the vertical block of granulated gel, have been obtained. Immunoelectrophoresis with the use of P. pseudomallei aqueous saline extract has revealed that antisera to electrophoretic fractions contain antibodies mainly to the antigens of the corresponding fractions, which shows that this technique ensures the effective separation of P. pseudomallei biopolymers by their electrophoretic motility and molecular weight. These antisera differ in their species specificity. Thus, antisera to antigens with anode motility have been found to contain antibodies mainly to P. pseudomallei antigens and antisera to electroneutral antigens or to those with cathode motility, to P. pseudomallei and P. mallei antigens.     

布鲁氏菌胞内生存机制研究进展

布鲁氏菌是一种胞内寄生菌,可以在专业和非专业吞噬细胞内生存和复制。当布鲁氏菌与细胞接触时,细菌可以通过受体分子进入细胞。布鲁氏菌在细胞内首先定位于早期吞噬体,然后,在胞内改变其运输方向,最终抵达其胞内复制部位内质网,开始大量复制。这种复制既不影响细胞的基本功能,也不诱导细胞的损伤。主要综述了布鲁氏菌对细胞的侵袭、胞内运输和复制的相关研究进展。     

Effect of Tetramicra brevifilum (Microspora) infection on respiratory-burst responses of turbot (Scophthalmus maximus L.) phagocytes

In vitro assays were performed to investigate microsporidian-induced intracellular and extracellular production of reactive oxygen species (ROS) by peritoneal-exudate adherent (PEA) cells from turbot. ROS production was quantified using the fluorescent reagents OxyBURST Green H2HFF BSA (extracellular) and OxyBURST Green H2DCFDA succinimidyl ester (intracellular). Five days before assay, the cells had been elicited in vivo by intraperitoneal injection of sodium thioglycollate or spores of Tetramicra brevifilum. Elicitation with spores led to a marked increase in the proportion of neutrophils among PEA cells. PEA cells from normal turbot showed considerable extracellular and intracellular ROS production in response to microsporidian spores. By contrast, PEA cells from microsporidian-infected turbot showed considerably reduced extracellular and intracellular ROS production in response to microsporidian spores. Extracellular ROS production was affected by the addition of infected turbot serum to the assay medium, regardless of whether the PEA cells had been obtained from normal or infected fish. The presence of microsporidian-infected turbot serum significantly reduced intracellular ROS production by PEA cells elicited with microsporidian spores. These results suggest that (a) microsporidian spores partially suppress the repiratory-burst response of turbot phagocytes; and (b) infected turbot serum contains substances capable of modulating the respiratory-burst response of turbot phagocytes to microsporidian spores.     

Expression, purification and characterization of C2 domain of milk fat globule-EGF-factor 8-L

Milk fat globule-EGF-factor 8-L (MFG-E8L) is secreted by activated macrophages and functions as a linker protein or opsonin between the dying cells and phagocytes. MFG-E8L recognizes the apoptotic or dying cells by specifically binding to Phosphatidylserine (PS) exposed on the outer cell surface and enhances the engulfment of the apoptotic cells by phagocytes, thereby preventing the inflammation and autoimmune response against intracellular antigens that can be released from the dying cells. MFG-E8L contains two EGF-like domains, P/T (proline/threonine) rich domain followed by two discoidin-like domains (C1 and C2). Recent studies have shown that the C2 domain of MFG-E8L is specifically involved in interaction with PS exposed on the apoptotic cells. Towards understanding this specific molecular interaction between the MFG-E8L C2 domain and PS, we expressed, purified the C2 domain of MFG-E8L and performed the binding studies with phospholipids by (31)P NMR experiment. We demonstrated that our recombinant construct and expression system were effective and allowed us to obtain the C2 domain and also showed that the purified C2 domain was stable and properly folded, and our (31)P NMR studies indicated that the C2 domain had specific binding with PS.     

The life strategy and self-regulation mechanisms of populations of the causative agents of sapronoses (exemplified by Pseudomonas pseudomallei)

The strategy of the selection (life) of P. pseudomallei has been defined as C-competitiveness, combining the advantages of the limited (r and K) types of the ecological strategies of microorganisms and ensuring their good capacity of survival in soil biota. The self-regulation mechanisms of P. pseudomallei populations in the environment are determined by the type of their strategy of selection, which also determines the place of this species among other organisms inhabiting the soil. C-competitiveness of P. pseudomallei permits the realization of the self-support of its populations under changing conditions of their habitat, in particular in vivo.     

Cellular and molecular mechanisms of internalization of mycobacteria by host cells

Mycobacteria are intracellular pathogens capable of invading mononuclear phagocytes, mucosal epithelial cells (including M cells) and Schwann cells. To enter cells, mycobacteria have been shown to interact with several molecules on macrophage and epithelial cell surfaces. This suggests adaptation to the host environment. In this review we address the strategies used by pathogenic mycobacteria to gain access to the intracellular environment.     

The molecular and cellular basis of pathogenesis in melioidosis: how does Burkholderia pseudomallei cause disease?

Melioidosis, a febrile illness with disease states ranging from acute pneumonia or septicaemia to chronic abscesses, was first documented by Whitmore & Krishnaswami (1912) . The causative agent, Burkholderia pseudomallei , was subsequently identified as a motile, gram-negative bacillus, which is principally an environmental saprophyte. Melioidosis has become an increasingly important disease in endemic areas such as northern Thailand and Australia ( Currie et al. , 2000 ). This health burden, plus the classification of B. pseudomallei as a category B biological agent ( Rotz et al. , 2002 ), has resulted in an escalation of research interest. This review focuses on the molecular and cellular basis of pathogenesis in melioidosis, with a comprehensive overview of the current knowledge on how B. pseudomallei can cause disease. The process of B. pseudomallei movement from the environmental reservoir to attachment and invasion of epithelial and macrophage cells and the subsequent intracellular survival and spread is outlined. Furthermore, the diverse assortment of virulence factors that allow B. pseudomallei to become an effective opportunistic pathogen, as well as to avoid or subvert the host immune response, is discussed. With the recent increase in genomic and molecular studies, the current understanding of the infection process of melioidosis has increased substantially, yet, much still remains to be elucidated.