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Aspergillus fumigatus, a ubiquitous fungus, causes invasive disease in immunocompromised humans. Although monocytes and antigen-specific CD4 T cells contribute to defense against inhaled fungal spores, how these cells interact during infection remains undefined. Investigating the role of inflammatory monocytes and monocyte-derived dendritic cells during fungal infection, we find that A. fumigatus infection induces an influx of chemokine receptor CCR2- and Ly6C-expressing inflammatory monocytes into lungs and draining lymph nodes. Depletion of CCR2+ cells reduced A. fumigatus conidial transport from lungs to draining lymph nodes, abolished CD4 T cell priming following respiratory challenge, and impaired pulmonary fungal clearance. In contrast, depletion of CCR2+Ly6Chi monocytes during systemic fungal infection did not prevent CD4 T cell priming in the spleen. Our findings demonstrate that pulmonary CD4 T cell responses to inhaled spores require CCR2+Ly6Chi monocytes and their derivatives, revealing a compartmentally restricted function for these cells in adaptive respiratory immune responses.
Inhalation of airborne fungal spores (conidia) is a daily event in mammalian life, and respiratory immune defenses provide effective and generally symptomless protection against invasive infection (Hohl and Feldmesser, 2007; Latge, 1999; Segal, 2009). Aspergillus fumigatus is a ubiquitous mold that, in immune compromised individuals, can cause invasive pulmonary infection leading to potentially lethal, disseminated disease. Though early defense against inhaled A. fumigatus spores is mediated by neutrophils (Bonnett et al., 2006; Gerson et al., 1984; Mehrad et al., 1999; Mircescu et al., 2009), protection against invasive disease in immunocompromised mice (Cenci et al., 1997, 2000) and humans (Hebart et al., 2002) also involves fungus-specific CD4 T cells. In immunocompromised patients, adoptive transfer of A. fumigatus-specific CD4 T cells can provide protection against invasive fungal infection (Beck et al., 2006; Perruccio et al., 2005).
Circulating monocytes have been implicated in defense against A. fumigatus, with evidence for direct killing of invasive fungal hyphae (Diamond et al., 1983; Roilides et al., 1994) and spores (Serbina et al., 2009a). A. fumigatus spores activate monocytes to express a broad range of cytokines, chemokines, and antimicrobial molecules (Cortez et al., 2006; Loeffler et al., 2009). TLR-mediated recognition of undefined fungal components and Dectin-1-mediated interactions with fungal β-glucans (Hohl et al., 2005) contribute to monocyte activation.
Monocytes are divided into subsets on the basis of chemokine receptor and Ly6C expression in mice and CD14 and CD16 expression in humans (Auffray et al., 2009b; Serbina et al., 2008). Murine Ly6Chi monocytes are commonly referred to as inflammatory monocytes and express CCR2, a chemokine receptor that promotes emigration from the bone marrow (BM) into the circulation (Serbina and Pamer, 2006). Ccr2−/− mice have increased susceptibility to viral and microbial infections (Kurihara et al., 1997; Robben et al., 2005; Serbina et al., 2003), in large part due to retention of monocytes in the BM (Serbina and Pamer, 2006). Ccr2−/− mice also have decreased Th1 CD4 T cell responses (Nakano et al., 2009; Peters et al., 2000, 2001), a defect that has been correlated to impaired trafficking of monocytes to sites of infection and diminished transport of antigen to draining lymph nodes (Peters et al., 2000) or to decreased monocyte recruitment to inflamed lymph nodes and diminished production of IL-12 at the time of T cell priming (Nakano et al., 2009). In chronic fungal infection models, CCR2 deficiency appears to be associated with Th2 CD4 T cell differentiation (Blease et al., 2000; Traynor et al., 2000). Thus, although increasing evidence implicates monocytes in the activation and differentiation of CD4 T cell responses to viral (Aldridge et al., 2009; Nakano et al., 2009), mycobacterial (Peters et al., 2001), parasitic (Leon et al., 2007), and fungal infections (Traynor et al., 2000), it remains unclear whether monocytes are essential for these processes.
Although CCR2-mediated signals promote emigration of Ly6Chi monocytes from the BM, the absence of CCR2 only reduces circulating monocyte levels by roughly 80% during homeostatic conditions (Serbina and Pamer, 2006). CCR2-independent emigration of Ly6Chi monocytes from the BM potentially confounds the interpretation of experiments using CCR2-deficient mice, given that peripheral tissues may be populated with sufficient numbers of monocytes and derivative cells in the steady state to obscure important phenotypes resulting from defective monocyte recruitment during infectious and inflammatory states. In addition, monocytes may employ CCR2-independent mechanisms to influence adaptive immune responses. Thus, an experimental system that targets monocytes and derivative cells for in vivo depletion would provide strong evidence regarding their role in triggering adaptive immune responses.
Herein, we have investigated the recruitment and activation of Ly6Chi monocytes upon infection with Aspergillus fumigatus and, by generating a transgenic mouse strain that enables complete depletion of Ly6Chi monocytes, determined that this cell population is essential for transport of fungal spores from the airways to draining lymph nodes. Whereas depletion of Ly6Chi monocytes abrogates CD4 T cells' responses to respiratory challenge with fungal spores, systemic immune responses in the spleen are unaffected. Our studies reveal an essential, compartmentalized function for Ly6Chi monocytes for the initiation of CD4 T cell responses following the inhalation of fungal spores.
To characterize the pulmonary inflammatory cell influx following intratracheal (i.t.) A. fumigatus infection, we analyzed dissociated lung cells from naive mice by using flow cytometry to define distinct DC, macrophage, monocyte, and neutrophil populations in the steady state (Figure 1A). Lung leukocytes (CD45+ cells) were analyzed for CD11c and MHC class II expression (Figure 1A), and CD11c+ cells were divided into CD103+ DCs (Figure 1A, R1, yellow gate), macrophages (Figure 1A, R2, green gate), or CD11b+ DCs (Figure 1A, R3, blue gate) in accordance with published results (Sung et al., 2006). Following i.t. challenge with A. fumigatus conidia, rapid numeric expansion of CD11b+ DCs, but not CD103+ DCs or macrophages, was observed (Figure 1A). Neutrophil (defined as CD11b+Ly6C+Ly6G+ cells) and monocyte (defined as CD11b+Ly6ChiLy6G− cells) numbers increased substantially as well (Figure 1B). We next examined whether infection-induced changes in monocytes and derivative populations depends on intact CCR2 signaling. Ccr2−/− mice were infected and found to have diminished numbers of pulmonary monocytes and CD11b+ DCs at 2 days postinfection (Figure 1B) compared to control mice. Loss of CCR2 signaling did not diminish pulmonary neutrophil influx (Figure 1B).
To define cell subsets that take up A. fumigatus conidia following i.t. inoculation and potentially contribute to CD4 T cell priming and differentiation, we infected mice with Alexa Fluor 633-labeled conidia and analyzed them at 2 days postinfection. Neutrophils and lung macrophages bound fluorescent conidia (Figure 1C), as anticipated from prior studies (reviewed in Latge, 1999). CD11b+ DCs, a cell population that expands numerically during respiratory fungal infection, bound fluorescent conidia, but CD103+ DCs, which do not increase in number following infection, did not bind labeled conidia in vivo.
The priming of A. fumigatus-specific CD4 T cells in the lung-draining mediastinal lymph node (MLN) can be observed as early as 4 days postinfection (Rivera et al., 2006). To determine the kinetics of conidial transport to the draining MLN, C57BL/6 mice were infected with 1–2 × 107 conidia, and the number of MLN CFUs was quantified at specified time points postinfection. At 15 hr postinfection, ~102 CFUs were cultured from the MLN (Figure 1D), and this number increased to ~103 CFUs by 48 hr postinfection, with a slight decline during the ensuing 48 hr. Pulmonary CFUs declined at each time point examined, with a nearly 10-fold drop between the 15 hr and 96 hr time points (Figure 4B). Thus, MLN conidial transport is rapid and peaks in the first 2 days postinfection, temporally coincident with the large pulmonary influx of monocytes and CD11b+ DCs.
Because CD11b+ DCs take up conidia and accumulate in a CCR2-dependent manner during respiratory fungal infection, a CCR2 reporter mouse was generated to track CCR2+Ly6Chimonocytes and their relationship to CD11b+ lung DCs. A bacterial artificial chromosome encoding the murine CCR2 locus was modified to place GFP under control of the endogenous CCR2 promoter and incorporated into the germline of C57BL/6 mice (Figure 2B; for details, see methods in Serbina et al., 2009b). In CCR2 reporter mice, surface staining with a CCR2-specific monoclonal antibody (Mack et al., 2001) and transgenic expression of GFP correlate closely in BM cells (Figure 2B). GFP expression is high on circulating Ly6Chi monocytes and diminished on Ly6Clo monocytes (Figure S1 available online); these monocyte subsets express high and low levels of CCR2, respectively (Geissmann et al., 2003).
Although recent studies have shown that CD11b+ and CD103+ DCs both express CCR2 (Jakubzick et al., 2008b), characterization of naive CCR2 reporter mice revealed that CD11b+ DCs express higher levels of the GFP transgene compared to CD103+ DCs in the lung (Figure 2C). GFP transgene expression was not detected on neutrophils (data not shown) or autofluorescent lung CD11c+ macrophages from CCR2 reporter mice by flow cytometric analysis.
During respiratory fungal infection, the number of GFP+ cells in the lungs of CCR2 reporter mice nearly triples in the first 2 days postinfection (Figure 2D), and virtually all GFP+ cells express CD11b+ (Figure 2E). Approximately 15%–20% of CD11b+GFP+ cells contain fluorescent conidia (Figure 2F, left, red gate); this subset expresses high levels of CD11c (Figure 2G, red line) and MHC class II (data not shown), whereas GFP+ cells that did not contain fluorescent conidia (Figure 2F, left, blue gate) express little or no CD11c. This result suggests that monocytes rapidly convert to CD11b+ DCs upon or prior to conidial uptake.
Adoptive transfer experiments were performed to examine monocyte differentiation during respiratory fungal infection. CD45.1+CD45.2+ BM monocytes from CCR2 reporter mice were purified on the basis of GFP expression and transferred into CD45.2+ C57BL/6 recipient mice (Figure 3A). One-half of the recipient mice were infected with A. fumigatus 30 min later. The lungs of all experimental groups were harvested 3 days postinfection and analyzed by flow cytometry. CD45.1+GFP+ cells were found in the lungs of naive and infected recipient mice (Figure 3B), though the frequency and number of CD45.1+GFP+cells were higher in infected mice than in naive mice by a factor of ~2 and ~3, respectively. In infected mice, CD45.1+GFP+ cells in the lung express high levels of CD11c and MHC class II, whereas transferred CD45.1+GFP+ cells recovered from the lungs of naive mice (Figure 3C) express marginal levels of CD11c and MHC class II, consistent with the CD11b+Ly6C+Ly6G− flow cytometric phenotype of lung monocytes. Thus, the inflammatory response to respiratory fungal infection promotes monocyte differentiation into CD11b+ lung DCs that are associated with conidial uptake. We did not observe CD45.1+GFP+ cells in the CD103+ DC or macrophage gate in plots of stained lung cells from recipient mice (data not shown).
To examine whether GFP+ cells are associated with conidia in the MLN, we analyzed the MLN cell composition in CCR2 reporter mice at 48 hr postinfection, which corresponds to the peak in MLN A. fumigatus CFUs. At this time point, 2–3 × 104 GFP+CD11b+ cells accumulated in the MLN of infected (Figures 4A and 4B), but not naïve, mice. The majority of MLN GFP+CD11b+ cells express CD11c (Figure 4C, red gate) with a minor CD11c− population (Figure 4C, blue gate). MLN GFP+CD11b+CD11c+ cells express high levels of MHC class II and CD86 (Figure 4D), whereas GFP+CD11b+CD11c− cells do not. Thus, on the basis of flow cytometric characterization, MLN GFP+CD11b+CD11c+ cells closely resemble lung CD11b+ DCs.
Because CD11b+ DCs take up conidia in the lung, we expected to find fluorescent conidia in the corresponding MLN GFP+CD11b+CD11c+ cell population. Following infection with AF633-labeled conidia, ~5% of MLN GFP+CD11b+CD11c+ cells bound fluorescent conidia (Figure 4E, left), whereas GFP+CD11b+CD11c− cells did not (Figure 4E, right), suggesting that monocyte-derived CD11b+ lung DCs transport conidia to the MLN.
GFP+CD11b+ cells were sorted from the MLN of infected mice 48 hr postinfection and cultured ex vivo with naive, A. fumigatus-specific Af3.16 CD4 T cells (Rivera et al., 2006) in the presence of exogenously added Aspergillus antigens. Under these conditions, GFP+CD11b+ cells stimulated the proliferation of Af3.16 CD4 T cells, measured by tritiated thymidine incorporation (Figure 4F) and IL-2 release (data not shown), as efficiently as CD11c+ splenic DCs purified from mice injected with Flt3L-secreting tumor cells. These results demonstrate that GFP+CD11b+ MLN cells isolated from A. fumigatus-infected mice have the capacity to prime naive fungus-specific CD4 T cells ex vivo.
To determine whether monocytes and derivative cells actively transport conidia to the MLN and to analyze their role in CD4 T cell priming, we generated a CCR2 depleter mouse using the diphtheria toxin (DT)-induced cell ablation strategy (Saito et al., 2001). The BAC clone RP23-182D4 was modified to encode a simian DT receptor (DTR) and enhanced cyan fluorescent protein (CFP). The DTR and CFP modules were separated by a linker sequence that contains an aphthovirus 2A cleavage site and was optimized for fluorescence (Figures 5A and S2). Two candidate founder mice were derived following oocyte injections, and a single CCR2 depleter founder line was expanded.
CFP expression in CCR2 depleter BM cells corresponds closely to CCR2 Ab staining (Figure S3A). Similar to CCR2 reporter mice, BM Ly6Chi monocytes from CCR2 depleter mice uniformly express high levels of the fluorescent transgene (Figure S3B) and stain for the simian DTR transgene using an anti-human DTR Ab (Figure S3C). Circulating Ly6Chi and Ly6Clo monocytes express high levels and low levels of CFP, respectively (Figure S3D). CCR2 depleter mice were crossed to transgenic mice carrying a GFP transgene at the CX3CR1 locus (Jung et al., 2000). In progeny that contain both reporter genes, GFPloCFPhi monocytes (Figure 6B, orange gate) correspond to Ly6ChiCX3CR1loCCR2hi monocytes. Conversely, GFPhiCFPlo monocytes (Figure 6B, purple gate) correspond to Ly6CloCX3CR1hiCCR2lo monocytes. Thus, the major circulating monocyte subsets can be distinguished on the basis of transgene expression.
CCR2 depleter mice were injected with a single 10 ng/g body weight dose of DT. No overt toxicity was observed, and DT-treated mice did not succumb during a 10 day observation period. Within 24 hr, > 99% of circulating monocytes were ablated, with recovery incipient at 48–72 hr following DT administration (Figure 6C). The blood monocyte frequency reached pretreatment levels by day +4, with a further increase evident at day +8 (Figure 5C) and a return to homeostatic levels by day +10 (data not shown).
The finding that monocytes infiltrate the lungs of A. fumigatus-infected mice and differentiate into CD11b+ DCs that contain bound conidia is consistent with a role in MLN antigen delivery. It remains unclear, however, whether conidial transport to the MLN depends on DC uptake. Cell ablation experiments were performed to establish whether monocytes and derivative cells not only have the capacity to transport antigen to the MLN, but also are essential for this process.
CCR2 depleter and nontransgenic control mice were treated with a single DT dose and infected 24 hr later. The mice were euthanized 48 hr postinfection, and CFUs were determined in the MLN and lungs (Figure 5D). MLN CFUs in DT-treated CCR2 depleter mice were 85% lower than in nontransgenic controls, whereas lung CFUs were statistically equivalent in both groups (Figure 5D). Taken together with the MLN characterization of infected CCR2 reporter mice, these data indicate that monocyte-derived CD11b+ DCs represent the major transport mechanism for A. fumigatus from the lung to the MLN.
Further characterization of CCR2 depleter mice demonstrated that DT treatment led to a rapid depletion of BM Ly6C+ monocytes, with > 99% depletion within 12 hr of administration (data not shown). Of interest, MDPs, defined as CX3CR1+CD117+Lin− BM cells (Fogg et al., 2006), underwent depletion as well, with an ~90% reduction 24 hr following DT administration (Figure S4A), consistent with low-level expression of the CFP transgene (Figure S4B). Because MDPs not only give rise to monocytes, but also to nonmonocytic DC precursors, this finding suggested that DT treatment may affect splenic DC populations.
DT-induced cell depletion was, therefore, examined in lung and spleen samples from CCR2 depleter mice. A single DT dose led to the rapid depletion (by 12 hr) of lung- and spleen-resident CD11b+Ly6G−Ly6Chi monocytes, with a 2 log10 reduction in number (Figures 6A and 6B). In the lung, CD11b+ DCs and CD103+ DCs underwent significant depletion (>1 log10 decease in number), albeit with slower kinetics. The maximal extent of cell depletion was evident on day +3 post-DT administration (Figure 6A). Similar results were observed for lung CD11c+ macrophages. In contrast, the magnitude of DC depletion in the spleen was far less pronounced (Figure 6B). In three independent experiments, the number of CD8α+CD11c+MHC class II+ and CD11b+CD11c+MHC classII+ DCs in the spleen underwent a modest reduction, typically by 0.2–0.4 log10 units (Figure 6B).
Lethally irradiated C57BL/6 mice were reconstituted with CCR2 depleter BM as a control to determine whether CCR2 expression on nonhematopoietic cells influences cell depletion in the lung and spleen. The extent and kinetics of DC depletion in the lung and spleen were similar in recipient mice reconstituted with CCR2 depleter BM cells (Figure S5). Thus, DT administration to CCR2 depleter mice selectively affects DCs in the lung, and CD8α+ and CD11b+ DC subsets in the spleen are relatively unperturbed.
To determine whether the reduction in MLN antigen transport observed in CCR2 depleter mice affects antigen-specific CD4 T cell responses, we measured the proliferation, expansion, and trafficking of Af3.16 CD4 T cells in DT-treated CCR2 depleter mice 6 days postinfection. CCR2 depleter and nontransgenic C57BL/6 mice received 105 CFSE-labeled CD90.1+CD90.2+Af3.16 CD4 T cells and DT on day −1 and day +1 postinfection, with 1–2 × 107 A. fumigatus conidia. The number and CFSE dilution profiles of transferred Af3.16 CD4 T cells were examined in the MLN, lung, and airways.
Af3.16 CD4 T cells underwent priming and expansion in the MLN of DT-treated control mice (Figures 7A and 7B). In contrast, the frequency of transgenic cells in the MLN CD4 gate was much lower in DT-treated CCR2 depleter mice, and little dilution of the CFSE label was observed (Figures 7A and 7B). Overall, Af3.16 CD4 T cells in the MLN of infected control mice underwent > 1000-fold expansion compared to naive mice, whereas only an ~10-fold expansion was observed in the MLN of infected CCR2 depleter mice. In sum, the number of Af3.16 CD4 T cells was ~100-fold greater both in the MLN and lungs of infected control mice compared to CCR2 depleter mice (Figure 7C), indicating that a major defect in the initiation of the CD4 T cell adaptive immune response is associated with the depletion of transgene-expressing cells.
The lung fungal burden was examined in the same group of mice to test whether the loss of A. fumigatus-specific CD4 T cell responses is associated with impaired fungal clearance. In contrast to the day +2 time point (Figure 5D), CCR2 depleter mice had higher lung fungal burdens than control mice on day +6 postinfection (Figure 7D), consistent with the notion that CD4 T cell-dependent responses contribute to optimal antifungal defense. Thus, lung CD11b+ DC-mediated conidial transport to the MLN is required for the priming and proliferation of antigen-specific CD4 T cells in the lung, and interruption of this process coincides with reduced A. fumigatus pulmonary clearance.
Although DT treatment led to depletion of lung CD11b+ and CD103+ DCs, splenic CD11b+ and CD8α+ DC subsets were relatively insensitive to DT. To examine the functional consequences of compartment-specific DC depletion, CCR2 depleter mice treated with a single dose of DT were infected via the i.t. or i.v. route, and the expansion of adoptively transferred Af3.16 TCR-Tg cells was measured in the lung and spleen, respectively. The number of splenic Af3.16 CD4 T cells was equivalent in CCR2 depleter and control mice infected via the i.v. route (Figure 7D), whereas the number of pulmonary Af3.16 CD4 T cells was severely reduced in CCR2 depleter mice compared to the control group infected via the i.t. route.
Similar results were observed in CCR2 depleter and control mice infected via the i.t. or i.v. route with an ActA− Listeria monocytogenes strain that expresses the Mycobacterium tuberculosis antigen ESAT-6. CCR2 depleter mice infected via the i.t. route showed a major defect in the number of lung ESAT-6-specific CD4 T cells (Gallegos et al., 2008), whereas CCR2 depleter mice infected via the i.v. route displayed normal expansion of splenic ESAT-6-specific CD4 T cells (Figure S6). These data demonstrate a compartment-specific role for monocyte-derived DCs in initiating adaptive immune responses to microbial pathogens.
Monocytes rapidly mobilize and rapidly differentiate in response to microbial challenges. Although monocytes are recruited to diverse host tissues and are implicated in innate and adaptive responses to viral and other microbial pathogens, their compartment-specific contributions to host defense remain incompletely defined. In part, our limited understanding of the role of monocytes in antimicrobial defense stems from the fact that selective in vivo depletion of monocytes has been difficult to achieve. Our results using a CCR2 depleter mouse strain demonstrate an essential role for monocytes in the priming and expansion of CD4 T cell responses following inhalation of a microbial pathogen. Loss of CD4 T cell priming following monocyte depletion correlates with a marked decrease in transport of fungal conidia to lung-draining MLNs and an ensuing defect in fungal clearance from the lung, thus implicating CCR2+Ly6Chi monocytes and derivative CD11b+ DCs in this critical early step in the adaptive immune response.
We found that transferred BM monocytes rapidly differentiate in the presence of infection and express high levels of CD11c and MHC class II, giving rise to lung CD11b+ DCs. Under these conditions, we did not observe monocyte differentiation into CD103+ DCs or pulmonary macrophages (data not shown). Furthermore, we did not observe CD11c and MHC class II upregulation upon transfer of cells into naive mice. It is likely that microbially induced inflammatory responses promote monocyte differentiation into CD11b+ DCs with the capacity to take up and process microbial cargo at the portal of entry. CD11b+ and CD103+ lung DCs have been reported to discriminate between soluble and particulate forms of a model antigen, with uptake of the soluble form primarily by CD11b+ DCs and the particulate form primarily by CD103+ DCs (Jakubzick et al., 2008a). However, our results suggest that CD11b+ DCs bind inhaled conidia, particles with an average diameter of 2–4 μm. In murine models of tuberculosis and leishmaniasis, CD11b+ DCs take up fluorescent mycobacteria and parasites at infection sites and remain associated with the labeled microbes in the draining LNs (Leon et al., 2007; Wolf et al., 2007). Influenza virus nucleo-protein is found in the cytoplasm of migratory CD11b+ and plamacytoid DCs isolated from the lung-draining lymph nodes. (GeurtsvanKessel et al., 2008). An explanation for the differential uptake of microbial antigen by CD103− and CD103+ DCs is the distinct complement of phagocytic receptors expressed by these DC subsets. Recent microarray analyses demonstrate that mRNA levels of receptors (e.g., dectin-1 and CD209) involved in conidial uptake are higher in CD103− than in CD103+ DCs (del Rio et al., 2008; Serrano-Gomez et al., 2004). This difference may explain the in vivo difference in fungal cell uptake by CD11b+ and CD103+ lung DCs.
Much has been learned recently about the development of tissue DCs from precursors in the BM. Geissmann and colleagues identified a common macrophage and DC precursor (MDP) (Fogg et al., 2006) that gives rise to DC subsets both in lymphoid and nonlymphoid tissues. However, splenic conventional CD8α− and CD8α+DCs (cDCs) develop in an Flt3L-dependent manner (Waskow et al., 2008) via a common DC precursor (CDP) in the BM and a pre-DC intermediate that can traffic from the BM to the spleen (Liu et al., 2007, 2009; Naik et al., 2006, 2007; Onai et al., 2007). Monocytes and descendent cells arise from MDPs as well (Auffray et al., 2009a; Fogg et al., 2006), albeit via a distinct developmental pathway (Liu et al., 2009). Recent studies using parabiosis, latex bead labeling, and adoptive transfer techniques found that circulating monocytes (Jakubzick et al., 2008b; Landsman and Jung, 2007; Landsman et al., 2007) have the capacity to give rise to lung DCs and macrophages in the steady state, with CCR2+Ly6Chi monocytes preferentially giving rise to CD103+ DCs and Ly6Clo monocytes preferentially giving rise to CD11b+ DCs (Jakubzick et al., 2008b). It is clear that these steady-state pathways of monocyte differentiation are redirected during microbial infection (Serbina et al., 2008). For example, Ly6Chi monocytes infiltrating the spleens of Listeria monocytogenes-infected mice differentiate into TNF and iNOS-producing DCs (Tip-DCs) that are largely uninfected (Serbina et al., 2003). In contrast, in the setting of respiratory A. fumigatus infection, Ly6Chi monocytes differentiate into CD11b+ DCs upon uptake of fungal conidia. This may explain differences in our study from results seen in the steady state (Jakubzick et al., 2008b).
The distinct developmental pathways of lung and splenic DCs likely contribute to the different degree of DC ablation noted in lung and splenic subsets in toxin-treated CCR2 depleter mice (Figure 6). Depletion of pulmonary CD11b+ and CD103+ DCs upon DT treatment of CCR2-DTR mice may result from depletion of monocyte precursors, but it is possible that tissue DC populations recently derived from monocytes continue to express DTR and thus are eliminated by toxin treatment. The delayed kinetics of lung DC subset depletion, however, suggests that monocyte loss is a more likely explanation for DC loss. Furthermore, the half-life of airway DCs is short. Holt and colleagues estimated a turnover time of ~2 days based on BM chimera experiments (Holt et al., 1994). In addition, respiratory DCs undergo basal migration to secondary lymphoid tissues via afferent lymphatics (Legge and Braciale, 2003). It is thus likely that pulmonary DC subsets are sensitive to the levels of circulating precursor cells, particularly following microbial challenge or in inflammatory states.
The finding that splenic CD4 T cell responses remain intact whereas pulmonary CD4 T cell responses are impaired may appear surprising, given the observation that MDPs are targeted in CCR2 depleter mice following toxin administration. Though bromodeoxyuridine labeling experiments suggests that both splenic subsets have half-lives on the order of 1.5–3 days (Kamath et al., 2000), more recent data show that splenic DCs may undergo limited cell division in situ (Liu et al., 2007) and extend the half-life of lymphoid organ DCs to 5–7 days. This latter estimate may contribute to differences in depletion seen in our experiments, given DT-induced depletion of the common MDP precursor. Consistent with this view, we observed that splenic cDCs were completely depleted in CCR2 depleter mice if the DT injection schedule was extended to four injections over 8 days (data not shown).
How do CCR2-expressing monocytes influence T cell responses? In our experiments, we demonstrate that they are necessary to transport conidia to draining lymph nodes. Although we demonstrate that monocyte-derived CD11b+ DCs prime naive T cells ex vivo, we cannot be certain that they are performing this function in vivo. Thus, the possibility remains that monocytes transport conidia to lymph nodes and then transfer antigen to lymph node-resident DCs. During influenza virus infection, this scenario appears highly likely for the priming of CD8 T cell responses by MLN resident CD11b− CD8α+ DCs (Belz et al., 2004) or CD11b− CD8α− DCs and CD4 T cell responses by MLN CD11b− CD8α− DCs (GeurtsvanKessel et al., 2008), given that these subsets do not participate in viral antigen delivery to the MLN. The recent development of mice with defined genetic lesions in lymph node-resident CD8α+ DC development (Hildner et al., 2008) may provide a framework to address these questions in more detail.
Invasive aspergillosis (IA) is a disease of the highly immunocompromised host, occurring most commonly in patients undergoing allogeneic BM transplantation (Segal, 2009). Although neutropenia is a well-appreciated risk factor for invasive fungal infection, recent studies have demonstrated that human monocyte subsets can also directly inhibit germination of A. fumigatus conidia (Serbina et al., 2009a). Whether human or murine monocytes play a critical role for the success of vaccine strategies that target IA remains an important line of investigation. Preclinical studies have evaluated a large number of proteinaceous, lipidic, and carbohydrate antigens in combination with adjuvants or DCs as vaccine candidates (Bozza et al., 2009; Cenci et al., 2000; Torosantucci et al., 2005, 2009). Our demonstration that selective depletion of monocytes in the setting of A. fumigatus infection abrogates pathogen-specific CD4 T cell responses suggests that temporary loss of monocytes in clinical settings has important implications for CD4 T cell-dependent vaccination strategies and the development of adaptive antifungal defenses.
C57BL/6, C57BL/6.SJL, Ccr2−/−, CX3CR1(gfp/gfp) (purchased from Jackson Laboratories), Af3.16 TCR-Tg (Rivera et al., 2006), and ESAT-6 clone 7 TCR-Tg (Gallegos et al., 2008) mice were housed and bred at the MSKCC Research Animal Resource Center. The generation of CCR2 reporter and CCR2 depleter mice is described in Serbina et al. (2009b) and the Supplemental Experimental Procedures, respectively. All strains were generated on or backcrossed > 10 generations on the C57BL/6 background.
Diphtheria toxin was obtained from List Biological Laboratories (Cat. No. 150), reconstituted at 1 mg/ml in PBS, and frozen at −80°C. Mice received 10 ng/g DT via the i.p. route in 0.2–0.3 ml PBS.
Mice were infected via the i.t. (1–2 × 107 conidia) or i.v. (105 conidia) route with A. fumigatus strain Af293. For fluorescent labeling, 1–2 × 108 conidia were incubated with 100 μg/ml Alexa Fluor 633 succinimidyl ester (Invitrogen) at 37°C for 1 hr according to manufacturer's instructions.
For adoptive transfer of 105 Af3.16 CD4 T cells via lateral tail vein injection, CD4 T cells from the spleens and LNs of Af3.16 TCR-Tg mice were collected, labeled with 5 μM CFSE (Invitrogen) as indicated, and purified by MACS using CD4 microbeads (Miltenyi Biotech). For adoptive transfer of BM monocytes, single-cell BM suspensions from CD45.1+CD45.2+CCR2 reporter mice were stained with APC-linked anti-CD3, -CD11c, -CD19, -NK1.1, and -Ter119, and GFP+APC− cells were isolated by sorting on a MoFlo flow cytometer (Cytomation) and injected into recipient mice.
Single-cell lung, spleen, BM, and lymph node suspensions were prepared. Lungs and spleens were minced in PBS, 5% FCS, 3 mg/ml collagenase type IV (Worthington), and 20 U/ml DNase (Roche) and were incubated at 37°C for 60 min and 15 min, respectively. Following RBC lysis, cell suspensions were enumerated using a Z2 Coulter counter (Beckman Instruments) with a 6–15 μm window, stained with antibodies listed in the Supplemental Experimental Procedures, and analyzed on a BD LSR II cytometer.
GFP+CD11b+ DCs were sorted from the MLN of A. fumigatus-infected CCR2 reporter mice 2 days postinfection, and 3.5 × 104 cells were seeded per well in a 96-well plate in quadruplicate. MACS-purified CD11c+ control DCs (5 × 104 per well) were harvested from the spleens of C57BL/6 mice injected with a B16-Flt3L tumor line. 5 × 104 Af3.16 CD4 T cells from Rag-2−/− donors were purified over anti-CD4 microbeads and added to each well containing APCs. A. fumigatus hyphal antigens were added at a 1:200 final dilution together with 1 μg/ml voriconazole (Pfizer). After 2 days, culture supernatant IL-2 levels were measured by ELISA. Fresh media and 1 μCi of 3[H]-thymidine were added to the wells, and the samples were processed for liquid scintillation analysis 1 day later.
The unpaired Student's t test was used for statistical analysis using GraphPad Prism 5.0 software. p < 0.05 was considered statistically significant.
We thank Ingrid Leiner for outstanding technical support and Ting Jia, Alexander Lesokhin, and Natalya Serbina for helpful comments and suggestions. This work was supported by NIH grants K08 AI071998 to T.M.H., K01 CA117914-01A1 to A.R., F32 AI074248 to A.G., and R01 AI067359 and P01 CA-023766 to E.G.P.
Supplemental Data include Supplemental Experimental Procedures and six figures and can be found with this article online at http://www.cell.com/cell-host-microbe/supplemental/S1931-3128(09)00349-7.