Cell biology and molecular ecology of Francisella tularensis

Francisella tularensis is a highly infectious intracellular bacterium that causes the fulminating disease tularemia, which can be transmitted between mammals by arthorpod vectors. Genomic studies have shown that the F. tularensis has been undergoing genomic decay with the most virulent strains having the lowest number of functional genes. Entry of F. tularensis into macrophages is mediated by looping phagocytosis and is associated with signalling through Syk tyrosine kinase. Within macrophages and arthropod‐derived cells, the Francisella‐containing phagosome matures transiently into an acidified late endosome‐like phagosome with limited fusion to lysosomes followed by rapid bacterial escape into the cytosol within 30–60 min, and bacterial proliferation within the cytosol. The Francisella pathogenicity island, which potentially encodes a putative type VI secretion system, is essential for phagosome biogenesis and bacterial escape into the cytosol within macrophages and arthropod‐derived cells. Initial sensing of F. tularensis in the cytosol triggers IRF‐3‐dependent IFN‐β secretion, type I IFNR‐dependent signalling, activation of the inflammasome mediated by caspase‐1, and a pro‐inflammatory response, which is suppressed by triggering of SHIP. The past few years have witnessed a quantum leap in our understanding of various aspects of this organism and this review will discuss these remarkable advances.     

Francisella tularensis membrane complexome by blue native/SDS-PAGE

The study of membrane proteins and membrane protein complexes (MPC) provides crucial information in the field of bacterial physiology and pathogenesis research. The method of blue native polyacrylamide gel electrophoresis and its combination with SDS-PAGE (BN/SDS-PAGE) were here employed to study the membrane complexome of an intracellular bacterium Francisella tularensis, the causative agent of a severe disease tularemia. In the presented study we describe the subunit composition and stoichiometry of several MPC involved in various cell functions (oxidative phosphorylation, membrane transport, cell division, membrane or periplasmic proteins folding, iron storage, phospholipid and cell envelope biosynthesis). Moreover, some undocumented or hypothetical MPC with possible connection to virulence factors were also proposed and some newly detected subunits were assigned to known complexes. The BN/SDS-PAGE combined with mass spectrometry appeared to be a strong tool in the investigation of membrane proteins and complexes and thus successfully complements the traditional electrophoresis approaches.     

Type A Francisella tularensis Acid Phosphatases Contribute to Pathogenesis

Different Francisella spp. produce five or six predicted acid phosphatases (AcpA, AcpB, AcpC, AcpD, HapA and HapB). The genes encoding the histidine acid phosphatases (hapA, hapB) and acpD of F. tularensis subsp. Schu S4 strain are truncated or disrupted. However, deletion of HapA (FTT1064) in F. tularensis Schu S4 resulted in a 33% reduction in acid phosphatase activity and loss of the four functional acid phosphatases in F. tularensis Schu S4 (ΔABCH) resulted in a>99% reduction in acid phosphatase activity compared to the wild type strain. All single, double and triple mutants tested, demonstrated a moderate decrease in mouse virulence and survival and growth within human and murine phagocytes, whereas the ΔABCH mutant showed >3.5-fold decrease in intramacrophage survival and 100% attenuation of virulence in mouse. While the Schu S4 ΔABCH strain was attenuated in the mouse model, it showed only limited protection against wild type challenge. F. tularensis Schu S4 failed to stimulate reactive oxygen species production in phagocytes, whereas infection by the ΔABCH strain stimulated 5- and 56-fold increase in reactive oxygen species production in neutrophils and human monocyte-derived macrophages, respectively. The ΔABCH mutant but not the wild type strain strongly co-localized with p47^phox and replicated in macrophages isolated from p47^phox knockout mice. Thus, F. tularensis Schu S4 acid phosphatases, including the truncated HapA, play a major role in intramacrophage survival and virulence of this human pathogen.     

Control of Francisella tularensis Intracellular Growth by Pulmonary Epithelial Cells

The virulence of F. tularensis is often associated with its ability to grow in macrophages, although recent studies show that Francisella proliferates in multiple host cell types, including pulmonary epithelial cells. Thus far little is known about the requirements for killing of F. tularensis in the non-macrophage host cell types that support replication of this organism. Here we sought to address this question through the use of a murine lung epithelial cell line (TC-1 cells). Our data show that combinations of the cytokines IFN-γ, TNF, and IL-17A activated murine pulmonary epithelial cells to inhibit the intracellular growth of the F. tularensis Live Vaccine Strain (LVS) and the highly virulent F. tularensis Schu S4 strain. Although paired combinations of IFN-γ, TNF, and IL-17A all significantly controlled LVS growth, simultaneous treatment with all three cytokines had the greatest effect on LVS growth inhibition. In contrast, Schu S4 was more resistant to cytokine-induced growth effects, exhibiting significant growth inhibition only in response to all three cytokines. Since one of the main antimicrobial mechanisms of activated macrophages is the release of reactive nitrogen intermediates (RNI) via the activity of iNOS, we investigated the role of RNI and iNOS in Francisella growth control by pulmonary epithelial cells. NOS2 gene expression was significantly up-regulated in infected, cytokine-treated pulmonary epithelial cells in a manner that correlated with LVS and Schu S4 growth control. Treatment of LVS-infected cells with an iNOS inhibitor significantly reversed LVS killing in cytokine-treated cultures. Further, we found that mouse pulmonary epithelial cells produced iNOS during in vivo respiratory LVS infection. Overall, these data demonstrate that lung epithelial cells produce iNOS both in vitro and in vivo, and can inhibit Francisella intracellular growth via reactive nitrogen intermediates.     

土拉弗朗西斯菌胶体金免疫层析快速检测方法的建立

目的建立胶体金免疫层析技术快速定量检测土拉弗朗西斯菌。方法利用胶体金标记和双抗体夹心免疫层析技术,建立土拉弗朗西斯菌的快速检测方法,评价其特异性和敏感性,并拟合检测曲线进行定量检测。在面粉、饼干、果冻、梨汁等食品样品中添加土拉弗朗西斯菌的FopA蛋白模拟污染样品,评价该方法对固体、半固体、液体等食品样品的检测能力。结果该法可在10min内完成定性和定量检测,灵敏度为750ng／ml,线性范围750～24000ng/ml、回收率为56．7％-89．2％。结论所建立的检测土拉弗朗西斯菌的胶体金免疫层析方法,能快速、灵敏、特异、准确地检测样品中的土拉弗朗西斯菌,适用于现场快速检测。     

Identification of Francisella tularensis in natural water samples by PCR

Abstract Francisella tularensis , the causative agent of the epizootic disease tularemia in mammals, can be isolated from mud and water. To study the spread and persistence of Francisella tularensis in water, different strategies for pre-treatment of natural water samples prior to identification of the bacterium by polymerase chain reaction (PCR) were evaluated. A method for handling of samples taken from natural waters was developed. Applied on natural water samples amended with F. tularensis , the method rendered identification by PCR reproducible and it resulted in an amplified Francisella -specific product in all samples from natural waters tested. In addition, by employing primers targeting conserved regions of the 16S rDNA the presence of bacteria was demonstrated in all samples investigated. The results presented will, in combination with other techniques that allow identification, improve studies on the epizootiology and epidemiology of the genus Francisella .     

Francisella tularensis resistance to bactericidal action of normal human serum

Abstract Lipopolysaccharide and outer membranes from the three virulent encapsulated (Cap⁺) strains of three subspecies of Francisella tularensis and their isogenic avirulent capsule-deficient (Cap⁻) mutants were isolated. It was shown that the Cap⁻ cells and their outer membranes almost completely consumed the available complement of normal human serum whereas Cap⁻ LPS (R-LPS), Cap⁺ cells and their components activated the complement less effectively. Absorption of normal human serum with Cap⁻ strain dramatically reduced the complement consumption for homologous strain and its surface structures. This reduction reflected the loss of bactericidal antibodies. Addition of antibodies to whole cells of F. tularensis completely restored complement activity. The cross-absorbing experiments demonstrated that Cap⁻ cells more effectively deplete bactericidal antibodies than homologous virulent strain. From these results it can be concluded that normal human serum is bactericidal for serum-sensitive Cap⁻ F. tularensis strains through the action of complement initiated by the classical complement pathway and serum resistance of virulent strains is not due to absence of targets for bactericidal antibodies, but is due to their low accessibility because of O-side chains of lipopolysaccharide.     

Repression of Inflammasome by Francisella tularensis during Early Stages of Infection

Francisella tularensis is an important human pathogen responsible for causing tularemia. F. tularensis has long been developed as a biological weapon and is now classified as a category A agent by the Centers for Disease Control because of its possible use as a bioterror agent. F. tularensis represses inflammasome; a cytosolic multi-protein complex that activates caspase-1 to produce proinflammatory cytokines IL-1β and IL-18. However, the Francisella factors and the mechanisms through which F. tularensis mediates these suppressive effects remain relatively unknown. Utilizing a mutant of F. tularensis in FTL_0325 gene, this study investigated the mechanisms of inflammasome repression by F. tularensis. We demonstrate that muted IL-1β and IL-18 responses generated in macrophages infected with F. tularensis live vaccine strain (LVS) or the virulent SchuS4 strain are due to a predominant suppressive effect on TLR2-dependent signal 1. Our results also demonstrate that FTL_0325 of F. tularensis impacts proIL-1β expression as early as 2 h post-infection and delays activation of AIM2 and NLRP3-inflammasomes in a TLR2-dependent fashion. An enhanced activation of caspase-1 and IL-1β observed in FTL_0325 mutant-infected macrophages at 24 h post-infection was independent of both AIM2 and NLRP3. Furthermore, F. tularensis LVS delayed pyroptotic cell death of the infected macrophages in an FTL_0325-dependent manner during the early stages of infection. In vivo studies in mice revealed that suppression of IL-1β by FTL_0325 early during infection facilitates the establishment of a fulminate infection by F. tularensis. Collectively, this study provides evidence that F. tularensis LVS represses inflammasome activation and that F. tularensis-encoded FTL_0325 mediates this effect.     

Signatures of T cells as correlates of immunity to Francisella tularensis

Tularemia or vaccination with the live vaccine strain (LVS) of Francisella tularensis confers long-lived cell-mediated immunity. We hypothesized that this immunity depends on polyfunctional memory T cells, i.e., CD4⁺ and/or CD8⁺ T cells with the capability to simultaneously express several functional markers. Multiparametric flow cytometry, measurement of secreted cytokines, and analysis of lymphocyte proliferation were used to characterize in vitro recall responses of peripheral blood mononuclear cells (PBMC) to killed F. tularensis antigens from the LVS or Schu S4 strains. PBMC responses were compared between individuals who had contracted tularemia, had been vaccinated, or had not been exposed to F. tularensis (naïve). Significant differences were detected between either of the immune donor groups and naïve individuals for secreted levels of IL-5, IL-6, IL-10, IL-12, IL-13, IFN-γ, MCP-1, and MIP-1β. Expression of IFN-γ, MIP-1β, and CD107a by CD4⁺CD45RO⁺ or CD8⁺CD45RO⁺ T cells correlated to antigen concentrations. In particular, IFN-γ and MIP-1β strongly discriminated between immune and naïve individuals. Only one cytokine, IL-6, discriminated between the two groups of immune individuals. Notably, IL-2- or TNF-α-secretion was low. Our results identify functional signatures of T cells that may serve as correlates of immunity and protection against F. tularensis.     

Sensitivity spectrum of Francisella tularensis to antibiotics and synthetic antibacterial drugs

Sensitivity of 6 F. tularensis strains to 57 antibiotics and synthetic antibacterial drugs was studied. It was shown that the strains were highly sensitive to aminoglycosides, tetracyclines, anzamycins, quinolones, chloramphenicol, nitrofurantoin, nitroxoline, novobiocin and fusidin and resistant to penicillins, cephalosporins, polypeptides, vancomycin and sulfanylamides. The interrace differences in F. tularensis could be detected only by sensitivity to erythromycin, oleandomycin and spiramycin. There was observed no cross resistance to streptomycin and other aminoglycosides in F. tularensis. Assay of F. tularensis sensitivity to antibacterial drugs of various groups with the rapid photometric procedure and the agar diffusion method revealed that the results were highly comparable.     

A new cell assay to determine the virulence of Francisella tularensis

A cell culture assay to determine the virulence of Francisella tularensis was devised. Murine cell lines P388 and J774 were significantly more susceptible to F. tularensis Schu4 than the attenuated live vaccine strain. The ability of F. tularensis strains to cause cell death correlated with their virulence to mice. Use of this assay with infected cells separated from susceptible uninfected cells by a membrane with 0.1 μm pores, failed to demonstrate possible diffusible exotoxins produced by F. tularensis.     

iTRAQ quantitative analysis of Francisella tularensis ssp. holarctica live vaccine strain and Francisella tularensis ssp. tularensis SCHU S4 response to different temperatures and stationary phases of growth

Proteomics has been shown to significantly contribute to the investigation of the pathogenicity of the extremely infectious bacteria Francisella tularensis. In this study, the authors employed iTRAQ quantitative proteomic analysis in order to monitor alterations in proteomes of F. tularensis ssp. holarctica live vaccine strain and F. tularensis ssp. tularensis SCHU S4 associated with the cultivation at different temperatures or in the stationary phase. Correlated production of the identified proteins studied by the exploratory statistical analysis revealed novel candidates for virulence factors that were regulated in a similar manner to the genes encoded in the Francisella Pathogenicity Island. Moreover, the assessment of the adaptation of live vaccine strain and SCHU S4 strain to the examined stimuli uncovered differences in their physiological responses to the stationary phase of growth.     

Active suppression of the pulmonary immune response by Francisella tularensis Schu4

Francisella tularensis is an obligate, intracellular bacterium that causes acute, lethal disease following inhalation. As an intracellular pathogen F. tularensis must invade cells, replicate, and disseminate while evading host immune responses. The mechanisms by which virulent type A strains of Francisella tularensis accomplish this evasion are not understood. Francisella tularensis has been shown to target multiple cell types in the lung following aerosol infection, including dendritic cells (DC) and macrophages. We demonstrate here that one mechanism used by a virulent type A strain of F. tularensis (Schu4) to evade early detection is by the induction of overwhelming immunosuppression at the site of infection, the lung. Following infection and replication in multiple pulmonary cell types, Schu4 failed to induce the production of proinflammatory cytokines or increase the expression of MHCII or CD86 on the surface of resident DC within the first few days of disease. However, Schu4 did induce early and transient production of TGF-beta, a potent immunosuppressive cytokine. The absence of DC activation following infection could not be attributed to the apoptosis of pulmonary cells, because there were minimal differences in either annexin or cleaved caspase-3 staining in infected mice compared with that in uninfected controls. Rather, we demonstrate that Schu4 actively suppressed in vivo responses to secondary stimuli (LPS), e.g., failure to recruit granulocytes/monocytes and stimulate resident DC. Thus, unlike attenuated strains of F. tularensis, Schu4 induced broad immunosuppression within the first few days after aerosol infection. This difference may explain the increased virulence of type A strains compared with their more attenuated counterparts.     

Contribution of Citrulline Ureidase to Francisella tularensis Strain Schu S4 Pathogenesis

The citrulline ureidase (CTU) activity has been shown to be associated with highly virulent Francisella tularensis strains, including Schu S4, while it is absent in avirulent or less virulent strains. A definitive role of the ctu gene in virulence and pathogenesis of F. tularensis Schu S4 has not been assessed; thus, an understanding of the significance of this phenotype is long overdue. CTU is a carbon-nitrogen hydrolase encoded by the citrulline ureidase (ctu) gene (FTT0435) on the F. tularensis Schu S4 genome. In the present study, we evaluated the contribution of the ctu gene in the virulence of category A agent F. tularensis Schu S4 by generating a nonpolar deletion mutant, the Δctu mutant. The deletion of the ctu gene resulted in loss of CTU activity, which was restored by transcomplementing the ctu gene. The Δctu mutant did not exhibit any growth defect under acellular growth conditions; however, it was impaired for intramacrophage growth in resting as well as gamma interferon-stimulated macrophages. The Δctu mutant was further tested for its virulence attributes in a mouse model of respiratory tularemia. Mice infected intranasally with the Δctu mutant showed significantly reduced bacterial burden in the lungs, liver, and spleen compared to wild-type (WT) Schu S4-infected mice. The reduced bacterial burden in mice infected with the Δctu mutant was also associated with significantly lower histopathological scores in the lungs. Mice infected with the Δctu mutant succumbed to infection, but they survived longer and showed significantly extended median time to death compared to that shown by WT Schu S4-infected mice. To conclude, this study demonstrates that ctu contributes to intracellular survival, in vivo growth, and pathogenesis. However, ctu is not an absolute requirement for the virulence of F. tularensis Schu S4 in mice.Francisella tularensis, the etiological agent of tularemia, is a category A bioterrorism agent. High infectivity, ease of intentional aerosol dissemination, and lack of a licensed vaccine have made Francisella a potential biowarfare agent (5, 12, 34). The two major subspecies of Francisella have been divided on the basis of virulence, epidemiological distribution, and biochemical reactions (51). F. tularensis subspecies tularensis (type A strain) is highly virulent and the major cause of tularemia in North America, whereas F. tularensis subspecies holarctica (type B strain), prevalent in Europe and Asia, is less virulent. Biochemically, type A strains produce acid from glycerol and exhibit citrulline ureidase (CTU) activity, while type B strains do not exhibit these activities (21). In contrast to these biochemical differences, very limited variation is seen at the genetic level (25, 41), suggesting that differences in virulence between type A and B strains may arise from differential gene expression by nearly homologous genomes. The highly virulent Schu S4 strain represents type A F. tularensis subspecies tularensis and was originally isolated from a clinical case of tularemia in Ohio in 1941. To date, only a few virulence-associated genes have been characterized in this strain (22, 36, 37, 48), and its virulence determinants still remain poorly understood.CTU, a member of the carbon-nitrogen hydrolase family protein encoded by the F. tularensis genome (FTT0435), degrades citrulline into ornithine, carbon dioxide, and ammonia (10). Citrulline is generated during the catabolism of arginine by bacterial arginine deiminase (ADI) (40, 47). Ornithine generated by citrulline degradation is either exchanged for arginine by an arginine-ornithine transporter or utilized for the generation of polyamines and energy in the form of ATP (40). Citrulline is also produced by macrophages during conversion of l-arginine and oxygen to nitric oxide (NO) by inducible NO synthase (iNOS). Citrulline thus formed can be recycled to l-arginine through an arginine-citrulline cycle, which not only regulates intracellular availability of l-arginine but, in turn, maintains a sustained production of NO by macrophages (19). However, unlike citrulline, macrophages have little or no capacity to convert ornithine, the breakdown product of citrulline into l-arginine (4). Recent reports have demonstrated that reactive nitrogen species derived from NO are critical for clearance of F. tularensis (27, 29). In addition, ammonia generated by degradation of citrulline has been proposed to play a role in alkalization of endosomal pH leading to phagosomal maturation arrest (25). Thus, interruption of the arginine-citrulline cycle through the degradation of citrulline into ornithine, CO₂, and ammonia by CTU may assume an important role in the virulence of F. tularensis.Until recently, CTU activity has been used to differentiate strains of F. tularensis with high virulence from strains with low virulence or avirulent strains (45). Previous studies have shown that the majority of virulent F. tularensis type A strains exhibit high CTU activity while strains lacking this enzyme activity are either less virulent or avirulent (10, 11). However, a direct relationship between CTU activity and virulence of F. tularensis could not be established. A majority of these previous studies were based on comparisons of CTU activity in naturally occurring wild-type (WT) virulent type A strains with that in less virulent or avirulent type B variants of F. tularensis. In the current study, a genetic approach was used to directly assess the role of CTU activity in the pathogenesis and virulence of the F. tularensis Schu S4 strain.