Contribution of Lipid Mediators in Divergent Outcomes following Acute Bacterial and Viral Lung Infections in the Obese Host

Obesity is considered an important comorbidity for a range of noninfectious and infectious disease states including those that originate in the lung, yet the mechanisms that contribute to this susceptibility are not well defined. In this study, we used the diet-induced obesity (DIO) mouse model and two models of acute pulmonary infection, Francisella tularensis subspecies tularensis strain SchuS4 and SARS-CoV-2, to uncover the contribution of obesity in bacterial and viral disease. Whereas DIO mice were more resistant to infection with SchuS4, DIO animals were more susceptible to SARS-CoV-2 infection compared with regular weight mice. In both models, neither survival nor morbidity correlated with differences in pathogen load, overall cellularity, or influx of inflammatory cells in target organs of DIO and regular weight animals. Increased susceptibility was also not associated with exacerbated production of cytokines and chemokines in either model. Rather, we observed pathogen-specific dysregulation of the host lipidome that was associated with vulnerability to infection. Inhibition of specific pathways required for generation of lipid mediators reversed resistance to both bacterial and viral infection. Taken together, our data demonstrate disparity among obese individuals for control of lethal bacterial and viral infection and suggest that dysregulation of the host lipidome contributes to increased susceptibility to viral infection in the obese host.

Circulating T Cells Are Not Sufficient for Protective Immunity against Virulent Francisella tularensis

Pulmonary infections elicit a combination of tissue-resident and circulating T cell responses. Understanding the contribution of these anatomically distinct cellular pools in protective immune responses is critical for vaccine development. Francisella tularensis is a highly virulent bacterium capable of causing lethal systemic disease following pulmonary infection for which there is no currently licensed vaccine. Although T cells are required for survival of F. tularensis infection, the relative contribution of tissue-resident and circulating T cells is not completely understood, hampering design of effective, long-lasting vaccines directed against this bacterium. We have previously shown that resident T cells were not sufficient to protect against F. tularensis, suggesting circulating cells may serve a critical role in host defense. To elucidate the role of circulating T cells, we used a model of vaccination and challenge of parabiotic mice. Intranasally infected naive mice conjoined to immune animals had increased numbers of circulating memory T cells and similar splenic bacterial burdens as vaccinated-vaccinated pairs. However, bacterial loads in the lungs of naive parabionts were significantly greater than those observed in vaccinated-vaccinated pairs, but despite early control of F. tularensis replication, all naive-vaccinated pairs succumbed to infection. Together, these data define the specific roles of circulating and resident T cells in defense against infection that is initiated in the pulmonary compartment but ultimately causes disseminated disease. These data also provide evidence for employing vaccination strategies that elicit both pools of T cells for immunity against F. tularensis and may be a common theme for other disseminating bacterial infections.

Cutting Edge: Lung-Resident T Cells Elicited by SARS-CoV-2 Do Not Mediate Protection against Secondary Infection

Immunity to pulmonary infection typically requires elicitation of lung-resident T cells that subsequently confer protection against secondary infection. The presence of tissue-resident T cells in severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) convalescent patients is unknown. Using a sublethal mouse model of coronavirus disease 2019, we determined if SARS-CoV-2 infection potentiated Ag-specific pulmonary resident CD4⁺ and CD8⁺ T cell responses and if these cells mediated protection against secondary infection. S protein-specific T cells were present in resident and circulating populations. However, M and N protein-specific T cells were detected only in the resident T cell pool. Using an adoptive transfer strategy, we found that T cells from SARS-CoV-2 immune animals did not protect naive mice. These data indicate that resident T cells are elicited by SARS-CoV-2 infection but are not sufficient for protective immunity.

Temporal Requirement for Pulmonary Resident and Circulating T Cells during Virulent Francisella tularensis Infection

The lung is a complex organ with anatomically distinct pools of T cells that play specific roles in combating infection. Our knowledge regarding the generation and/or maintenance of immunity by parenchymal or circulating T cells has been gathered from either persistent (>60 d) or rapidly cleared (<10 d) infections. However, the roles of these distinct T cell pools in infections that are cleared over the course of several weeks are not understood. Clearance of the highly virulent intracellular bacterium Francisella tularensis subspecies tularensis (Ftt) following pulmonary infection of immune animals is a protracted T cell-dependent process requiring ∼30-40 d and serves as a model for infections that are not acutely controlled. Using this model, we found that intranasal vaccination increased the number of tissue-resident CD4⁺ effector T cells, and subsequent challenge of immune mice with Ftt led to a significant expansion of polyfunctional parenchymal CD4⁺ effector T cells compared with the circulating pool. Despite the dominant in vivo response by parenchymal CD4⁺ T cells after vaccination and challenge, circulating CD4⁺ T cells were superior at controlling intracellular Ftt replication in vitro. Further examination in vivo revealed temporal requirements for resident and circulating T cells during Ftt infection. These requirements were in direct contrast to other pulmonary infections that are cleared rapidly in immune animals. The data in this study provide important insights into the role of specific T cell populations that will be essential for the design of novel effective vaccines against tularemia and potentially other agents of pulmonary infection.

Unique Francisella Phosphatidylethanolamine Acts as a Potent Anti-Inflammatory Lipid

Virulent Francisella tularensis subsp. tularensis (Ftt) is a dynamic, intracellular, bacterial pathogen. Its ability to evade and rapidly suppress host inflammatory responses is considered a key element for its profound virulence. We previously established that Ftt lipids play a role in inhibiting inflammation, but we did not determine the lipid species mediating this process. Here, we show that a unique, abundant, phosphatidylethanolamine (PE), present in Francisella, contributes to driving the suppression of inflammatory responses in human and mouse cells. Acyl chain lengths of this PE, C24: 0 and C10: 0, were key to the suppressive capabilities of Francisella PE. Addition of synthetic PE 24: 0-10: 0 resulted in the accumulation of PE in host cells for up to 24 h of incubation, and recapitulated the inhibition of inflammatory responses observed with native Ftt PE. Importantly, this novel PE significantly inhibited inflammatory responses driven by a medically and globally important flavivirus, dengue fever virus. Thus, targeting these lipids and/or the pathways that they manipulate represents a new strategy to combat immunosuppression engendered by Ftt, but they also show promise as a novel therapeutic intervention for significant viral infections.

The Ability to Acquire Iron Is Inversely Related to Virulence and the Protective Efficacy of Francisella tularensis Live Vaccine Strain

Francisella tularensis is a highly infectious bacterial pathogen that causes the potentially fatal disease tularemia. The Live Vaccine Strain (LVS) of F. tularensis subsp. holarctica, while no longer licensed as a vaccine, is used as a model organism for identifying correlates of immunity and bacterial factors that mediate a productive immune response against F. tularensis. Recently, it was reported that two biovars of LVS differed in their virulence and vaccine efficacy. Genetic analysis showed that they differ in ferrous iron homeostasis; lower Fe2+ levels contributed to increased resistance to hydrogen peroxide in the vaccine efficacious LVS biovar. This also correlated with resistance to the bactericidal activity of interferon γ-stimulated murine bone marrow-derived macrophages. We have extended these findings further by showing that a mutant lacking bacterioferritin stimulates poor protection against Schu S4 challenge in a mouse model of tularemia. Together these results suggest that the efficacious biovar of LVS stimulates productive immunity by a mechanism that is dependent on its ability to limit the toxic effects of oxidative stress by maintaining optimally low levels of intracellular Fe2+.

Inclusion of Epitopes That Expand High-Avidity CD4+ T Cells Transforms Subprotective Vaccines to Efficacious Immunogens against Virulent Francisella tularensis

T cells are the immunological cornerstone in host defense against infections by intracellular bacterial pathogens, such as virulent Francisella tularensis spp. tularensis (Ftt). The general paucity of novel vaccines for Ftt during the past 60 y can, in part, be attributed to the poor understanding of immune parameters required to survive infection. Thus, we developed a strategy utilizing classical immunological tools to elucidate requirements for effective adaptive immune responses directed against Ftt. Following generation of various Francisella strains expressing well-characterized lymphocytic choriomeningitis virus epitopes, we found that survival correlated with persistence of Ag-specific CD4(+) T cells. Function of these cells was confirmed in their ability to more effectively control Ftt replication in vitro. The importance of understanding the Ag-specific response was underscored by our observation that inclusion of an epitope that elicits high-avidity CD4(+) T cells converted a poorly protective vaccine to one that engenders 100% protection. Taken together, these data suggest that improved efficacy of current tularemia vaccine platforms will require targeting appropriate Ag-specific CD4(+) T cell responses and that elucidation of Francisella epitopes that elicit high-avidity CD4(+) T cell responses, specifically in humans, will be required for successful vaccine development.

Inclusion of non-Francisella epitopes promotes expansion of high avidity, antigen-specific CD4+ T cells for improvement of existing Francisella vaccines

Francisella tularensis subsp. tularensis strain SchuS4 (Ftt) is a highly virulent bacterial pathogen and the causative agent of tularemia. There are no licensed tularemia vaccines and experimental live vaccine strains (LVS) vary in their protective efficacy and are poorly defined. Development of novel vaccines will require improvement of protection over the existing LVS and preferably incorporation of well-defined epitopes. However, protective epitopes for tularemia have not been identified. Surviving tularemia requires a strong polyfunctional CD4+ T cell response. Due to the importance of the CD4+ T cell response, we hypothesized ectopic expression of an epitope recognized by high avidity CD4+ T cells would enhance existing vaccine efficacy, regardless of the epitope’s origin. gp61 and LLO are well characterized CD4+ T cell epitopes derived from LCMV and Listeria, respectively, and are recognized by C57Bl/6, but not Balb/c mice. Expression of gp61 or LLO during primary infection with LVS or Ftt improved survival of C57Bl/6, but not Balb/c mice, indicating the presence of low numbers of high avidity CD4+ precursor T cells alters survival during Francisella infection. Furthermore, mice vaccinated with LVS gp61 had significantly improved survival during low and high dose secondary Ftt infection and decreased bacterial burdens compared to controls. Together, this demonstrates that improved efficacy of current tularemia vaccine platforms is achieved by properly targeting appropriate antigen-specific cellular responses. Moreover, the elucidation of Francisella epitopes that elicit high-avidity CD4+ T cell responses, specifically in humans, will be required for successful vaccine development.

Mitochondrial ROS potentiates indirect activation of the AIM2 inflammasome

Activation of the inflammasome is important for the detection and clearance of cytosolic pathogens. In contrast to avirulent Francisella novicida (Fn), infection with virulent Francisella tularensis ssp tularensis does not trigger activation of the host AIM2 inflammasome. Here we show that differential activation of AIM2 following Francisella infection is due to sensitivity of each isolate to reactive oxygen species (ROS). ROS present at the outset of Fn infection contributes to activation of the AIM2 inflammasome, independent of NLRP3 and NADPH oxidase. Rather, mitochondrial ROS (mROS) is critical for Fn stimulation of the inflammasome. This study represents the first demonstration of the importance of mROS in the activation of the AIM2 inflammasome by bacteria. Our results also demonstrate that bacterial resistance to mROS is a mechanism of virulence for early evasion of detection by the host.

Virulent Francisella tularensis destabilize host mRNA to rapidly suppress inflammation

Highly virulent bacterial pathogens have evolved rapid means to suppress host inflammatory responses by unknown mechanisms. Here, we use virulent Francisella tularensis, the cause of lethal tularemia in humans, as a model to elucidate these mechanisms. We show that following infection of murine macrophages F. tularensis rapidly and selectively destabilizes mRNA containing adenylate-uridylate-rich elements that encode for cytokines and chemokines important in controlling bacterial infection. Degradation of host mRNA encoding interleukin (IL)-1β, IL-6 and CXCL1 did not require viable bacteria or de novo protein synthesis, but did require escape of intracellular organisms from endocytic vesicles into the host cytosol. The specific targeting of host mRNA encoding inflammatory cytokines and chemokines for decay by a bacterial pathogen has not been previously reported. Thus, our findings represent a novel strategy by which a highly virulent pathogen modulates host inflammatory responses critical to the evasion of innate immunity.

The Francisella O-antigen mediates survival in the macrophage cytosol via autophagy avoidance

Autophagy is a key innate immune response to intracellular parasites that promotes their delivery to degradative lysosomes following detection in the cytosol or within damaged vacuoles. Like Listeria and Shigella, which use specific mechanisms to avoid autophagic detection and capture, the bacterial pathogen Francisella tularensis proliferates within the cytosol of macrophages without demonstrable control by autophagy. To examine how Francisella evades autophagy, we screened a library of F. tularensis subsp. tularensis Schu S4 HimarFT transposon mutants in GFP-LC3-expressing murine macrophages by microscopy for clones localized within autophagic vacuoles after phagosomal escape. Eleven clones showed autophagic capture at 6 h post-infection, whose HimarFT insertions clustered to fourgenetic loci involved in lipopolysaccharidic and capsular O-antigen biosynthesis. Consistent with the HimarFT mutants, in-frame deletion mutants of two representative loci, FTT1236 and FTT1448c (manC), lacking both LPS and capsular O-antigen, underwent phagosomal escape but were cleared from the host cytosol. Unlike wild-type Francisella, the O-antigen deletion mutants were ubiquitinated, and recruited the autophagy adaptor p62/SQSTM1 and LC3 prior to cytosolic clearance. Autophagy-deficient macrophages partially supported replication of both mutants, indicating that O-antigen-lacking Francisella are controlled by autophagy. These data demonstrate the intracellular protective role of this bacterial surface polysaccharide against autophagy.

Alternative activation of macrophages and induction of arginase are not components of pathogenesis mediated by Francisella species

Virulent Francisella tularensis ssp tularensis is an intracellular, Gram negative bacterium that causes acute lethal disease following inhalation of fewer than 15 organisms. Pathogenicity of Francisella infections is tied to its unique ability to evade and suppress inflammatory responses in host cells. It has been proposed that induction of alternative activation of infected macrophages is a mechanism by which attenuated Francisella species modulate host responses. In this report we reveal that neither attenuated F. tularensis Live Vaccine Strain (LVS) nor virulent F. tularensis strain SchuS4 induce alternative activation of macrophages in vitro or in vivo. LVS, but not SchuS4, provoked production of arginase1 independent of alternative activation in vitro and in vivo. However, absence of arginase1 did not significantly impact intracellular replication of LVS or SchuS4. Together our data establish that neither induction of alternative activation nor expression of arginase1 are critical features of disease mediated by attenuated or virulent Francisella species.

Brucella modulates secretory trafficking via multiple type IV secretion effector proteins

The intracellular pathogenic bacterium Brucella generates a replicative vacuole (rBCV) derived from the endoplasmic reticulum via subversion of the host cell secretory pathway. rBCV biogenesis requires the expression of the Type IV secretion system (T4SS) VirB, which is thought to translocate effector proteins that modulate membrane trafficking along the endocytic and secretory pathways. To date, only a few T4SS substrates have been identified, whose molecular functions remain unknown. Here, we used an in silico screen to identify putative T4SS effector candidate proteins using criteria such as limited homology in other bacterial genera, the presence of features similar to known VirB T4SS effectors, GC content and presence of eukaryotic-like motifs. Using β-lactamase and CyaA adenylate cyclase reporter assays, we identified eleven proteins translocated into host cells by Brucella, five in a VirB T4SS-dependent manner, namely BAB1_0678 (BspA), BAB1_0712 (BspB), BAB1_0847 (BspC), BAB1_1671 (BspE) and BAB1_1948 (BspF). A subset of the translocated proteins targeted secretory pathway compartments when ectopically expressed in HeLa cells, and the VirB effectors BspA, BspB and BspF inhibited protein secretion. Brucella infection also impaired host protein secretion in a process requiring BspA, BspB and BspF. Single or combined deletions of bspA, bspB and bspF affected Brucella ability to replicate in macrophages and persist in the liver of infected mice. Taken together, these findings demonstrate that Brucella modulates secretory trafficking via multiple T4SS effector proteins that likely act coordinately to promote Brucella pathogenesis.

Many intracellular parasites ensure their survival and proliferation within host cells by secreting an array of effector molecules that modulate various cellular functions. Among these, Brucella abortus, the causative agent of the worldwide zoonosis brucellosis, controls the intracellular trafficking of its vacuole, the Brucella-containing vacuole (BCV), towards compartments of the secretory pathway via the expression of a Type IV secretion system (T4SS), VirB, which is thought to translocate effector proteins. Here, we have used bioinformatic algorithms and protein translocation reporter assays to identify novel Brucella proteins translocated into host cells, some of which are VirB T4SS substrates and targeted secretory pathway compartments when ectopically expressed in mammalian cells. Three VirB effectors, BspA, BspB and BspF, inhibited protein secretion and contributed to varying degrees to bacterial inhibition of host protein secretion, pathogen intracellular growth and persistence in the liver of infected mice. These findings demonstrate that Brucella modulates secretory trafficking via multiple T4SS effector proteins to promote Brucella pathogenesis.

Structure-Function Analysis of DipA, a Francisella tularensis Virulence Factor Required for Intracellular Replication

Francisella tularensis is a highly infectious bacterium whose virulence relies on its ability to rapidly reach the macrophage cytosol and extensively replicate in this compartment. We previously identified a novel Francisella virulence factor, DipA (FTT0369c), which is required for intramacrophage proliferation and survival, and virulence in mice. DipA is a 353 amino acid protein with a Sec-dependent signal peptide, four Sel1-like repeats (SLR), and a C-terminal coiled-coil (CC) domain. Here, we determined through biochemical and localization studies that DipA is a membrane-associated protein exposed on the surface of the prototypical F. tularensis subsp. tularensis strain SchuS4 during macrophage infection. Deletion and substitution mutagenesis showed that the CC domain, but not the SLR motifs, of DipA is required for surface exposure on SchuS4. Complementation of the dipA mutant with either DipA CC or SLR domain mutants did not restore intracellular growth of Francisella, indicating that proper localization and the SLR domains are required for DipA function. Co-immunoprecipitation studies revealed interactions with the Francisella outer membrane protein FopA, suggesting that DipA is part of a membrane-associated complex. Altogether, our findings indicate that DipA is positioned at the host–pathogen interface to influence the intracellular fate of this pathogen.

B1a cells enhance susceptibility to infection with virulent Francisella tularensis via modulation of NK/NKT cell responses

B1a cells are an important source of natural Abs, Abs directed against T-independent Ags, and are a primary source of IL-10. Bruton's tyrosine kinase (btk) is a cytoplasmic kinase that is essential for mediating signals from the BCR and is critical for development of B1a cells. Consequentially, animals lacking btk have few B1a cells, minimal Ab responses, and can preferentially generate Th1-type immune responses following infection. B1a cells have been shown to aid in protection against infection with attenuated Francisella tularensis, but their role in infection mediated by fully virulent F. tularensis is not known. Therefore, we used mice with defective btk (CBA/CaHN-Btk(XID)/J [XID mice]) to determine the contribution of B1a cells in defense against the virulent F. tularensis ssp. tularensis strain SchuS4. Surprisingly, XID mice displayed increased resistance to pulmonary infection with F. tularensis. Specifically, XID mice had enhanced clearance of bacteria from the lung and spleen and significantly greater survival of infection compared with wild-type controls. We revealed that resistance to infection in XID mice was associated with decreased numbers of IL-10-producing B1a cells and concomitant increased numbers of IL-12-producing macrophages and IFN-γ-producing NK/NKT cells. Adoptive transfer of wild-type B1a cells into XID mice reversed the control of bacterial replication. Similarly, depletion of NK/NKT cells also increased bacterial burdens in XID mice. Together, our data suggest B cell-NK/NKT cell cross-talk is a critical pivot controlling survival of infection with virulent F. tularensis.

Cytosolic clearance of replication-deficient mutants reveals Francisella tularensis interactions with the autophagic pathway

Cytosolic bacterial pathogens must evade intracellular innate immune recognition and clearance systems such as autophagy to ensure their survival and proliferation. The intracellular cycle of the bacterium Francisella tularensis is characterized by rapid phagosomal escape followed by extensive proliferation in the macrophage cytoplasm. Cytosolic replication, but not phagosomal escape, requires the locus FTT0369c, which encodes the dipA gene (deficient in intracellular replication A). Here, we show that a replication-deficient, ∆dipA mutant of the prototypical SchuS4 strain is eventually captured from the cytosol of murine and human macrophages into double-membrane vacuoles displaying the late endosomal marker, LAMP1, and the autophagy-associated protein, LC3, coinciding with a reduction in viable intracellular bacteria. Capture of SchuS4ΔdipA was not dipA-specific as other replication-deficient bacteria, such as chloramphenicol-treated SchuS4 and a purine auxotroph mutant SchuS4ΔpurMCD, were similarly targeted to autophagic vacuoles. Vacuoles containing replication-deficient bacteria were labeled with ubiquitin and the autophagy receptors SQSTM1/p62 and NBR1, and their formation was decreased in macrophages from either ATG5-, LC3B- or SQSTM1-deficient mice, indicating recognition by the ubiquitin-SQSTM1-LC3 pathway. While a fraction of both the wild-type and the replication-impaired strains were ubiquitinated and recruited SQSTM1, only the replication-defective strains progressed to autophagic capture, suggesting that wild-type Francisella interferes with the autophagic cascade. Survival of replication-deficient strains was not restored in autophagy-deficient macrophages, as these bacteria died in the cytosol prior to autophagic capture. Collectively, our results demonstrate that replication-impaired strains of Francisella are cleared by autophagy, while replication-competent bacteria seem to interfere with autophagic recognition, therefore ensuring survival and proliferation.

Low dose vaccination with attenuated Francisella tularensis strain SchuS4 mutants protects against tularemia independent of the route of vaccination

Tularemia, caused by the Gram-negative bacterium Francisella tularensis, is a severe, sometimes fatal disease. Interest in tularemia has increased over the last decade due to its history as a biological weapon. In particular, development of novel vaccines directed at protecting against pneumonic tularemia has been an important goal. Previous work has demonstrated that, when delivered at very high inoculums, administration of live, highly attenuated strains of virulent F. tularensis can protect against tularemia. However, lower vaccinating inoculums did not offer similar immunity. One concern of using live vaccines is that the host may develop mild tularemia in response to infection and use of high inoculums may contribute to this issue. Thus, generation of a live vaccine that can efficiently protect against tularemia when delivered in low numbers, e.g. <100 organisms, may address this concern. Herein we describe the ability of three defined, attenuated mutants of F. tularensis SchuS4, deleted for FTT0369c, FTT1676, or FTT0369c and FTT1676, respectively, to engender protective immunity against tularemia when delivered at concentrations of approximately 50 or fewer bacteria. Attenuated strains for use as vaccines were selected by their inability to efficiently replicate in macrophages in vitro and impaired replication and dissemination in vivo. Although all strains were defective for replication in vitro within macrophages, protective efficacy of each attenuated mutant was correlated with their ability to modestly replicate and disseminate in the host. Finally, we demonstrate the parenteral vaccination with these strains offered superior protection against pneumonic tularemia than intranasal vaccination. Together our data provides proof of principle that low dose attenuated vaccines may be a viable goal in development of novel vaccines directed against tularemia.

Selective subversion of autophagy complexes facilitates completion of the Brucella intracellular cycle

Autophagy is a cellular degradation process that can capture and eliminate intracellular microbes by delivering them to lysosomes for destruction. However, pathogens have evolved mechanisms to subvert this process. The intracellular bacterium Brucella abortus ensures its survival by forming the Brucella-containing vacuole (BCV), which traffics from the endocytic compartment to the endoplasmic reticulum (ER), where the bacterium proliferates. We show that Brucella replication in the ER is followed by BCV conversion into a compartment with autophagic features (aBCV). While Brucella trafficking to the ER was unaffected in autophagy-deficient cells, aBCV formation required the autophagy-initiation proteins ULK1, Beclin 1, and ATG14L and PI3-kinase activity. However, aBCV formation was independent of the autophagy-elongation proteins ATG5, ATG16L1, ATG4B, ATG7, and LC3B. Furthermore, aBCVs were required to complete the intracellular Brucella lifecycle and for cell-to-cell spreading, demonstrating that Brucella selectively co-opts autophagy-initiation complexes to subvert host clearance and promote infection.

The Francisella tularensis pathogenicity island encodes a secretion system that is required for phagosome escape and virulence

Francisella tularensis causes the human disease tularemia. F. tularensis is able to survive and replicate within macrophages, a trait that has been correlated with its high virulence, but it is unclear the exact mechanism(s) this organism uses to escape killing within this hostile environment. F. tularensis virulence is dependent upon the Francisella pathogenicity island (FPI), a cluster of genes that we show here shares homology with type VI secretion gene clusters in Vibrio cholerae and Pseudomonas aeruginosa. We demonstrate that two FPI proteins, VgrG and IglI, are secreted into the cytosol of infected macrophages. VgrG and IglI are required for F. tularensis phagosomal escape, intramacrophage growth, inflammasome activation and virulence in mice. Interestingly, VgrG secretion does not require the other FPI genes. However, VgrG and other FPI genes, including PdpB (an IcmF homologue), are required for the secretion of IglI into the macrophage cytosol, suggesting that VgrG and other FPI factors are components of a secretion system. This is the first report of F. tularensis FPI virulence proteins required for intramacrophage growth that are translocated into the macrophage.

Intracellular biology and virulence determinants of Francisella tularensis revealed by transcriptional profiling inside macrophages

Summary The highly infectious bacterium Francisella tularensis is a facultative intracellular pathogen, whose virulence requires proliferation inside host cells, including macrophages. Here we have performed a global transcriptional profiling of the highly virulent F. tularensis ssp. tularensis Schu S4 strain during its intracellular cycle within primary murine macrophages, to characterize its intracellular biology and identify pathogenic determinants based on their intracellular expression profiles. Phagocytosed bacteria rapidly responded to their intracellular environment and subsequently altered their transcriptional profile. Differential gene expression profiles were revealed that correlated with specific intracellular locale of the bacteria. Upregulation of general and oxidative stress response genes was a hallmark of the early phagosomal and late endosomal stages, while induction of transport and metabolic genes characterized the cytosolic replication stage. Expression of the Francisella Pathogenicity Island (FPI) genes, which are required for intracellular proliferation, increased during the intracellular cycle. Similarly, 27 chromosomal loci encoding putative hypothetical, secreted, outer membrane proteins or transcriptional regulators were identified as upregulated. Among these, deletion of FTT0383, FTT0369c or FTT1676 abolished the ability of Schu S4 to survive or proliferate intracellularly and cause lethality in mice, therefore identifying novel determinants of Francisella virulence from their intracellular expression profile.

Brucella intracellular replication requires trafficking through the late endosomal/lysosomal compartment

Upon entry into mammalian cells, the intracellular pathogen Brucella abortus resides within a membrane-bound compartment, the Brucella-containing vacuole (BCV), the maturation of which is controlled by the bacterium to generate a replicative organelle derived from the endoplasmic reticulum (ER). Prior to reaching the ER, Brucella is believed to ensure its intracellular survival by inhibiting fusion of the intermediate BCV with late endosomes and lysosomes, although such BCVs are acidic and accumulate the lysosomal-associated membrane protein (LAMP-1). Here, we have further examined the nature of intermediate BCVs using confocal microscopy and live cell imaging. We show that BCVs rapidly acquire several late endocytic markers, including the guanosine triphosphatase Rab7 and its effector Rab-interacting lysosomal protein (RILP), and are accessible to fluid-phase markers either delivered to the whole endocytic pathway or preloaded to lysosomes, indicating that BCVs interact with late endosomes and lysosomes. Consistently, intermediate BCVs are acidic and display proteolytic activity up to 12 h post-infection. Expression of dominant-negative Rab7 or overexpression of RILP significantly impaired the ability of bacteria to convert their vacuole into an ER-derived organelle and replicate, indicating that BCV maturation requires interactions with functional late endosomal/lysosomal compartments. In cells expressing dominant-negative Rab7[T22N], BCVs remained acidic, yet displayed decreased fusion with lysosomes. Taken together, these results demonstrate that BCVs traffic along the endocytic pathway and fuse with lysosomes, and such fusion events are required for further maturation of BCVs into an ER-derived replicative organelle.

Autophagy-mediated reentry of Francisella tularensis into the endocytic compartment after cytoplasmic replication

Intracellular bacterial pathogens evade the bactericidal functions of mammalian cells by physical escape from their phagosome and replication into the cytoplasm or through the modulation of phagosome maturation and biogenesis of a membrane-bound replicative organelle. Here, we detail in murine primary macrophages the intracellular life cycle of Francisella tularensis, a highly infectious bacterium that survives and replicates within mammalian cells. After transient interactions with the endocytic pathway, bacteria escaped from their phagosome by 1 h after infection and underwent replication in the cytoplasm from 4 to 20 h after infection. Unexpectedly, the majority of bacteria were subsequently found to be enclosed within large, juxtanuclear, LAMP-1-positive vacuoles called Francisella-containing vacuoles (FCVs). FCV formation required intracytoplasmic replication of bacteria. Using electron and fluorescence microscopy, we observed that the FCVs contained morphologically intact bacteria, despite fusing with lysosomes. FCVs are multimembranous structures that accumulate monodansylcadaverine and display the autophagy-specific protein LC3 on their membrane. Formation of FCVs was significantly inhibited by 3-methyladenine, confirming a role for the autophagic pathway in the biogenesis of these organelles. Taken together, our results demonstrate that, via autophagy, F. tularensis reenters the endocytic pathway after cytoplasmic replication, a process thus far undescribed for intracellular pathogens.

Chromosomal excision of TCRδ chain genes is dispensable for αβ T cell lineage commitment

TCRbeta, delta and gamma chain genes are assembled and expressed in double-negative thymocytes prior to alphabeta or gammadelta T cell lineage commitment. Thus, cells committed to the alphabeta T cell lineage can possess completely assembled TCRdelta and/or TCRgamma chain genes. However, these genes are not expressed. TCRgamma chain gene expression may be silenced through the activity of a cis-acting silencer element. In the TCRalpha/delta locus, the TCRdelta genes lie between the Valpha and Jalpha gene segments, which rearrange by deletion. Moreover, Valpha to Jalpha rearrangements occur on both alleles in essentially all developing alphabeta T cells. Consequently, both TCRdelta chain genes are excised from the chromosome and placed on extrachromosomal circles in mature alphabeta T cells. It has been proposed that this excision process is important for silencing TCRdelta gene expression and permitting alphabeta T cell lineage commitment. A gene-targeting Cre-loxP strategy was used to invert a 75-kb region of the TCRalpha/delta locus encompassing all the Jalpha gene segments, generating the TCRalpha/delta(I) allele. Initial Valpha to Jalpha rearrangements on the TCRalpha/delta(I) allele occur by inversion, resulting in chromosomal retention of TCRdelta chain genes. These TCRdelta chain genes can be productively rearranged and are expressed at levels similar to TCRdelta chain genes in gammadelta T cells. However, alphabeta T cell development appears unperturbed in TCRalpha/delta(I/I) mice. Thus, excision of TCRdelta genes from the chromosome per se is not required for commitment of developing lymphocytes to the alphabeta T cell lineage.

The B12/23 restriction is critically dependent on recombination signal nonamer and spacer sequences

Ag receptor variable region gene assembly is initiated through the formation of a synaptic complex which minimally includes the recombination-activating gene (RAG) 1/2 proteins and a pair of recombination signals (RSs) flanking the recombining gene segments. RSs are composed of conserved heptamer and nonamer sequences flanking relatively nonconserved spacers of 12 or 23 bp. RSs regulate variable region gene assembly within the context of the 12/23 rule which mandates that recombination only occurs between RSs of dissimilar spacer length. RSs can exert additional constraints on variable region gene assembly beyond imposing spacer length requirements. At a minimum this restriction, termed B12/23, is imposed on the Vbeta to DJbeta rearrangement step by the 5' Dbeta RS and is enforced at or before the DNA cleavage step of the V(D)J recombination reaction. In this study, the components of the 5' Dbeta RS required for enforcing the B12/23 rule are assessed on chromosomal substrates in vivo in the context of normal murine thymocyte development and on extrachromosomal substrates induced to undergo recombination in nonlymphoid cell lines. These analyses reveal that the integrity of the nonamer sequence as well as the highly conserved spacer nucleotides of the 5' Dbeta1 RS are critical for enforcing the B12/23 restriction. These findings have important implications for understanding the B12/23 restriction and the manner in which RS synaptic complexes are assembled in vivo.

T cell receptor CDR3 loop length repertoire is determined primarily by features of the V(D)J recombination reaction

The third complementarity-determining region (CDR) of the TCR alpha and beta chains forms loops that engage amino acid residues of peptides complexed with MHC. This interaction is central to the specific discrimination of antigenic-peptide-MHC complexes by the TCR. The TCRbeta chain CDR3 loop is encoded by the Dbeta gene segment and flanking portions of the Vbeta and Jbeta gene segments. The joining of these gene segments is imprecise, leading to significant variability in the TCRbeta chain CDR3 loop length and amino acid composition. In marked contrast to other pairing antigen-receptor chains, the TCR beta and alpha chain CDR3 loop size distributions are relatively narrow and closely matched. Thus, pairing of TCR alpha and beta chains with relatively similar CDR3 loop sizes may be important for generating a functional repertoire of alpha beta TCR. Here we show that the TCRbeta chain CDR3 loop size distribution is minimally impacted by TCRbeta chain or alpha beta TCR selection during thymocyte development. Rather, this distribution is determined primarily at the level of variable-region gene assembly, and is critically dependent on unique features of the V(D)J recombination reaction that ensure Dbeta gene segment utilization.

Cutting edge: targeting of V beta to D beta rearrangement by RSSs can be mediated by the V(D)J recombinase in the absence of additional lymphoid-specific factors

Assembly of TCRbeta variable region genes is ordered during thymocyte development with Dbeta to Jbeta rearrangement preceding Vbeta to DJbeta rearrangement. The 5'Dbeta 12-RSS is required to precisely and efficiently target Vbeta rearrangement beyond simply enforcing the 12/23 rule. By prohibiting direct Vbeta to Jbeta rearrangement, this restriction ensures Dbeta gene segment use in the assembly of essentially all TCRbeta variable region genes. In this study, we show that rearrangement of Vbeta 23-RSSs is significantly biased to the Dbeta 12-RSS over Jbeta 12-RSSs on extrachromosomal recombination substrates in nonlymphoid cells that express the recombinase-activating gene-1/2 proteins. These findings demonstrate that targeting of Vbeta to Dbeta rearrangement can be enforced by the V(D)J recombinase in the absence of lymphoid-specific factors other than the recombinase-activating gene-1/2 proteins.

Restrictions limiting the generation of DNA double strand breaks during chromosomal V(D)J recombination

Antigen receptor loci are composed of numerous variable (V), diversity (D), and joining (J) gene segments, each flanked by recombination signal sequences (RSSs). The V(D)J recombination reaction proceeds through RSS recognition and DNA cleavage steps making it possible for multiple DNA double strand breaks (DSBs) to be introduced at a single locus. Here we use ligation-mediated PCR to analyze DNA cleavage intermediates in thymocytes from mice with targeted RSS mutations at the endogenous TCRbeta locus. We show that DNA cleavage does not occur at individual RSSs but rather must be coordinated between RSS pairs flanking gene segments that ultimately form coding joins. Coordination of the DNA cleavage step occurs over great distances in the chromosome and favors intra- over interchromosomal recombination. Furthermore, through several restrictions imposed on the generation of both nonpaired and paired DNA DSBs, this requirement promotes antigen receptor gene integrity and genomic stability in developing lymphocytes undergoing V(D)J recombination.

Mechanisms that direct ordered assembly of T cell receptor beta locus V, D, and J gene segments

T cell receptor (TCR) beta variable region genes are assembled in progenitor T cells from germ-line Vbeta, Dbeta, and Jbeta segments via an ordered two-step process in which Dbeta to Jbeta rearrangements occur on both alleles before appendage of a Vbeta to a preexisting DJbeta complex. Direct joining of Vbeta segments to nonrearranged Dbeta or Jbeta segments, while compatible with known restrictions on the V(D)J recombination mechanism, are infrequent within the endogenous TCRbeta locus. We have analyzed mechanisms that mediate ordered Vbeta, Dbeta, and Jbeta assembly via an approach in which TCRbeta minilocus recombination substrates were introduced into embryonic stem cells and then analyzed for rearrangement in normal thymocytes by recombinase-activating gene 2-deficient blastocyst complementation. These analyses demonstrated that Vbeta segments are preferentially targeted for rearrangement to Dbeta as opposed to Jbeta segments. In addition, we further demonstrated that Vbeta segments can be appended to nonrearranged endogenous Dbeta segments in which we have eliminated the ability of Dbeta segments to join to Jbeta segments. Our findings are discussed in the context of the mechanisms that regulate the ordered assembly and utilization of V, D, and J segments.

Recombination signal sequences restrict chromosomal V(D)J recombination beyond the 12/23 rule

The genes encoding the variable regions of lymphocyte antigen receptors are assembled from variable (V), diversity (D) and joining (J) gene segments. V(D)J recombination is initiated by the recombinase activating gene (RAG)-1 and -2 proteins, which introduce DNA double-strand breaks between the V, D and J segments and their flanking recombination signal sequences (RSSs). Generally expressed DNA repair proteins then carry out the joining reaction. The conserved heptamer and nonamer sequences of the RSSs are separated by non-conserved spacers of 12 or 23 base pairs (forming 12-RSSs and 23-RSSs). The 12/23 rule, which is mediated at the level of RAG-1/2 recognition and cutting, specifies that V(D)J recombination occurs only between a gene segment flanked by a 12-RSS and one flanked by a 23-RSS. Vbeta segments are appended to DJbeta rearrangements, with little or no direct Vbeta to Jbeta joining, despite 12/23 compatibility of Vbeta 23-RSSs and Jbeta12-RSSs. Here we use embryonic stem cells and mice with a modified T-cell receptor (TCR)beta locus containing only one Dbeta (Dbeta1) gene segment and one Jbeta (Jbeta1) gene cluster to show that the 5' Dbeta1 12-RSS, but not the Jbeta1 12-RSSs, targets rearrangement of a diverse Vbeta repertoire. This targeting is precise and position-independent. This additional restriction on V(D)J recombination has important implications for the regulation of variable region gene assembly and repertoire development.