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Constrained Intracellular Survival of Mycobacterium tuberculosis in Human Dendritic Cells ¹

Ludovic Tailleux^2,*, Olivier Neyrolles^2,3,, Stéphanie Honoré-Bouakline, Emmanuelle Perret, Françoise Sanchez^*, Jean-Pierre Abastado, Philippe Henri Lagrange, Jean Claude Gluckman^*, Michelle Rosenzwajg^* and Jean-Louis Herrmann^4,

^* Institut National de la Santé et de la Recherche Médicale EPI-0013 and Laboratoire d’Immunologie Cellulaire et Immunopathologie de l’École Pratique des Hautes Études, and Service de Microbiologie, Hôpital Saint-Louis, Paris, France; Centre d’Imagerie Dynamique, Institut Pasteur, Paris, France; and Immuno-Designed Molecules, Institut de Recherches Biomédicales des Cordeliers, Paris, France.

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
Dendritic cells (DCs) are likely to play a key role in immunity against Mycobacterium tuberculosis, but the fate of the bacterium in these cells is still unknown. Here we report that, unlike macrophages (Ms), human monocyte-derived DCs are not permissive for the growth of virulent M. tuberculosis H37Rv. Mycobacterial vacuoles are neither acidic nor fused with host cell lysosomes in DCs, in a mode similar to that seen in mycobacterial infection of Ms. However, uptake of the fluid phase marker dextran, and of transferrin, as well as accumulation of the recycling endosome-specific small GTPase Rab11 onto the mycobacterial phagosome, are almost abolished in infected DCs, but not in Ms. Moreover, communication between mycobacterial phagosomes and the host-cell biosynthetic pathway is impaired, given that <10% of M. tuberculosis vacuoles in DCs stained for the endoplasmic reticulum-specific proteins Grp78/BiP and calnexin. This correlates with the absence of the fusion factor N-ethylmaleimide-sensitive factor onto the vacuolar membrane in this cell type. Trafficking between the vacuoles and the host cell recycling and biosynthetic pathways is strikingly reduced in DCs, which is likely to impair access of intracellular mycobacteria to essential nutrients and may thus explain the absence of mycobacterial growth in this cell type. This unique location of M. tuberculosis in DCs is compatible with their T lymphocyte-stimulating functions, because M. tuberculosis-infected DCs have the ability to specifically induce cytokine production by autologous T lymphocytes from presensitized individuals. DCs have evolved unique subcellular trafficking mechanisms to achieve their Ag-presenting functions when infected by intracellular mycobacteria.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
Mycobacterium tuberculosis, the causative agent of tuberculosis, affects up to one-third of the world population. The ability of the bacterium to create active or latent disease relies, at least in part, on the powerful mechanisms it has evolved to parasitize host macrophages (Ms)⁵ (1). Although Ms appear to be central for mycobacterial replication, interactions of the bacilli with other leukocytes, such as dendritic cells (DCs), are likely to play a key role in immunity to M. tuberculosis. DCs exhibit the unique ability to ingest pathogens at the site of infection and to migrate to secondary lymphoid organs, such as lymph nodes, where they present pathogen-derived Ags to naive T lymphocytes (2). Priming and activation of mycobacterial Ag-specific T lymphocytes are essential for protection against tuberculosis (3, 4). In vitro studies have shown that human and murine DCs undergo maturation on infection with various mycobacterial species, such as M. tuberculosis, the vaccine strain Mycobacterium bovis bacillus Calmette-Guérin (BCG) and Mycobacterium avium (5, 6, 7, 8, 9, 10, 11, 12, 13). Mycobacterium-infected DCs up-regulate MHC and costimulatory molecules and acquire the ability to prime naive T lymphocytes in vitro and in vivo when reinjected into animals. In vivo, it is likely that DCs contribute to the generation of protective cellular immunity against mycobacteria, in essence by polarizing T lymphocyte reactivity toward a type 1 profile. Indeed, in response to mycobacterial infection, DCs produce IL-12 (8, 10, 12), the function of which is to activate NK cells and naive T lymphocytes to produce type 1 cytokines (14) such as IFN-, which are essential for protection against mycobacterial infections (3, 4). A recent ex vivo study in mice has demonstrated that DCs are the major leukocyte population involved in early activation of naive T lymphocytes after infection with M. bovis BCG (15). Interactions between DCs present in the airway and mycobacteria are thus likely to be critical for mounting a protective immune response and for determining the outcome of infection. However, interactions of M. tuberculosis with DCs remain poorly documented, at least on the subcellular level. In particular, the ability of mycobacteria to replicate in DCs relative to Ms remains controversial (10, 15, 16), and the trafficking pathway of mycobacteria in DCs is still unknown, whereas it has been well delineated in Ms.

M. tuberculosis entry into Ms involves various surface receptors (17) and ends in the bacteria residing in vacuoles or phagosomes. Since the discovery by Armstrong and d’Arcy Hart (18) that phagosomes containing viable M. tuberculosis do not fuse with ferritin-loaded host cell lysosomes, numerous studies have shed light on the nature and the mechanisms of biogenesis of the mycobacterial vacuole (19). In particular, compared with phagolysosomes containing inert particles, the mycobacterial phagosome is only mildly acidic (pH 6.2), a feature thought to rely on the exclusion of the vesicular H⁺ATPase from the vacuole (20). In addition, the vacuole does not accumulate late endosomal and/or lysosomal proteins, such as the cation-independent mannose 6-phosphate receptor (ciM6PR) (21) or the small GTPases Rab7 and Rab9 (22, 23, 24). By contrast, the mycobacterial phagosome displays reduced clearance of early endosomal proteins, such as the small GTPase Rab5a (22) or the actin-binding coronin 1-like for tryptophan-alanine-rich coat protein (TACO) (24, 25), although the exact role of TACO in phagosome biogenesis remains to be fully elucidated (26). Furthermore, the phagosome is accessible within minutes to exogenously administered molecules, such as the fluid phase marker HRP or recycled transferrin, and it is enriched in transferrin receptor/CD71 (27, 28), indicating that intracellular mycobacteria maintain access to extracellular components and possibly essential nutrients, such as iron, via the host cell recycling pathway. The mycobacterial phagosome is subjected not only to fusion but also to fission events, because vesicular materials, containing mycobacterial Ags, can traffic from the phagosome to other subcellular compartments where Ags can be processed and loaded onto presentation molecules (29, 30, 31). Thus, despite its limited fusogenicity towards organelles of the deep endocytic pathway, the mycobacterial phagosome appears to be very dynamic indeed. This feature correlates with the continuous presence of various fusion and docking factors, such as the ATPase N-ethylmaleimide-sensitive factor (NSF), onto the phagosomal membrane, whereas these factors are rapidly lost by phagolysosomes containing inert particles (24, 32).

Comparing concomitantly infected Ms and DCs, we report that unlike human Ms, monocyte-derived DCs do not allow M. tuberculosis intracellular growth, even though bacteria are not killed. Mycobacterial persistence in DCs was found to be associated with location of bacilli within vacuoles that exhibited immature characteristics but reduced communication with the host cell recycling and biosynthetic pathways. This is probably a consequence of infection-induced maturation of DCs, and this process most likely impairs access of intracellular mycobacteria to extracellular components, including possible essential nutrients such as iron and cholesterol. Reduced connection of the mycobacterial vacuole with the DC recycling and biosynthetic pathways did not impair the stimulating capacity of DCs for autologous T lymphocytes from presensitized individuals.

	Materials and Methods

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Mycobacteria

M. tuberculosis strain H37Rv was grown in 7H9 broth or 7H11 agar supplemented with 10% oleic acid-albumin-dextrose catalase (Difco, BD Biosciences, Mountain View, CA) and glycerol and lacking Tween 80 or any other detergent because this could result in alteration of mycobacterial cell wall and virulence (33). Liquid cultures were grown for up to 12 days and stored at -80°C in 1- to 2-ml aliquots with 10% glycerol; these were then used for cell infection. Aliquots were enumerated after eliminating clumps by 25 to 30 passages through a needle (26-gauge 3/8; 0.45 x 10 for intradermal injection; BD Biosciences), and serial 10-fold dilutions in sterile distilled water with 1% BSA were made. Green-fluorescent protein (GFP)-expressing M. tuberculosis strain H37Rv (GFP-M. tuberculosis) carried the pEGFP plasmid (gift from G. Stewart, Imperial College, London, U.K.), which encodes resistance to hygromycin and harbors the gfp gene under the control of the mycobacterial Phsp60 constitutive promoter. In line with other reports (34), the presence of GFP in M. tuberculosis did not alter the growth ability of the bacilli under axenic conditions relative to wild-type M. tuberculosis (data not shown). Recombinant bacteria were cultured in the presence of 50 µg/ml hygromycin B (Boehringer Ingelheim, Ingelheim, Germany). Before infection, viability of mycobacteria, evaluated by the propidium iodide exclusion method, was always >90%. In some experiments, bacteria were killed either by heating for 20 min at 95°C or by a 30-min incubation at 37°C in PBS-4% paraformaldehyde (PBS-PFA). After fixation, PFA was extensively washed off with PBS.

DCs, Ms, and infection

Blood mononuclear cells from healthy volunteers (Etablissement Français du Sang, Paris, France) were isolated by Ficoll-Paque (Pharmacia, Peapack, NJ) centrifugation. T, B, and NK cells were depleted using M-450 Pan T/CD2 and M-450 Pan B/CD19 Dynabeads (Dynal, Oslo, Norway). Recovered cells, hereafter referred to as monocytes, were seeded at 2 x 10⁶ cells/well in six-well plates (Falcon; BD Biosciences, Pont de Claix, France) in 3 ml RPMI 1640 (BD Biosciences, Invitrogen, Paris, France) supplemented with 10% heat-inactivated FCS (Dutscher, Brumath, France), L-glutamine, GM-CSF (10 ng/ml; Schering-Plough, Kenilworth, NJ), and IL-4 (20 ng/ml) for DC cultures, or with M-CSF (M-CSF; 50 ng/ml; R&D Systems, Minneapolis, MN) for M cultures. Monocytes were allowed to differentiate into DCs or Ms for 6 days at 37°C in 5% CO₂ humidified atmosphere. In some cases, Ms were prepared as above, but with GM-CSF (10 ng/ml) instead of M-CSF. Cultures were fed every 2 days with complete medium containing full doses of cytokines. GM-CSF- and IL-13-monocyte-derived DCs were prepared as reported (35). Unless specified, DCs refers to GM-CSF/IL-4-induced monocytes and Ms to M-CSF-induced monocytes. In some cases (indicated in the figure legends), FCS was replaced by human AB pooled sera (Établissement Français du Sang). Before infection, M. tuberculosis H37Rv (expressing or not the GFP) was rapidly thawed and incubated overnight in 30 ml of 7H9 with glycerol and hygromycin. Bacteria were then washed three times with and resuspended in 1 ml RPMI 1640. Clumps were disassociated by 25–30 passages through a needle, followed by 5 min of sedimentation. The density of bacteria in the supernatant was checked at OD₆₀₀ and correlated to the numeration of the aliquot to allow 1-to-1 bacterium-per-cell infection. This was performed in six-well plates with 2 x 10⁶ cells in 3 ml medium containing the respective cytokines for Ms and DCs. After 6 h of incubation at 37°C, infected cells were washed three times in RPMI 1640 to remove extracellular bacteria and were incubated in fresh medium for a further 1–7 days. In experiments on the antimycobacterial effect of GM-CSF, M-CSF was replaced by GM-CSF 18 h before infection of Ms. Unless otherwise indicated, cytokines were maintained in culture throughout the course of infection. After 7 days of infection, the percentages of dead cells (dextran blue exclusion assay) were 25–40% for DCs and 50–75% for Ms. Enumeration of intracellular bacteria was performed at day 0 (6 h postinfection), day 1, day 3, day 5, and day 7. Cell supernatant was collected and centrifuged at 12,000 rpm to recover potential extracellular bacteria. Ms and DCs were lysed by cold distilled water with 0.1% Triton X-100. Bacteria were enumerated as previously mentioned and plated on 7H11. CFUs were scored after 3 wk at 37°C.

Flow cytometry analysis

DCs and Ms were harvested at indicated times and resuspended in 200 µl of PBS-2% heat-inactivated FCS. The cell suspension was then incubated for 30 min at 4°C with the appropriate Abs (listed below) at optimal dilutions. Cells were washed and fixed with PBS-PFA. Fluorescence was analyzed on a total of 10⁴ cells per sample using FACSCalibur and CellQuest software (BD Biosciences). PE-conjugated anti-CD14 and FITC-conjugated anti-CD1a Abs were from BD Biosciences and BD PharMingen, respectively.

Confocal microscopy analysis

Ms were cultured and infected onto glass coverslips and fixed for 30 min in PBS-PFA. DCs were allowed to adhere for 15 min on polylysine-coated coverslips before fixation. Cells were then permeabilized with 0.05% saponin and immunostained as described (31). Coverslips were observed under a TCS4D confocal microscope (Leica, Deerfield, IL), and sections <0.8 µm were scored and treated using AdobePhotoshop software (Adobe Systems, Mountain View, CA). Primary Abs were as follows: anti-Rab11, -Rab6, -calnexin, anti-M6PR (Affinity Bioreagent, Golden, CO); anti-NSF (Synaptic Systems, Göttingen, Germany), anti-TACO (gift from J. Pieters, Basel Institute for Immunology, Basel, Switzerland); anti-vacuolar H⁺ATPase (Synaptic Systems); anti-Grp78/Bip (StressGen Biotechnologies, Victoria, Canada), anti-Golgin97 (Molecular Probes, Eugene, OR). Cy3-conjugated anti-mouse and -rabbit secondary Abs were from Amersham Biosciences UK (Little Chalfont, U.K.). Cy5-conjugated anti-mouse Abs were from Jackson ImmunoResearch Laboratories (West Grove, PA). Alexa594-conjugated anti-goat Abs were from Molecular Probes. In experiments using Lysotracker DND-99 (Molecular Probes), infected cells were incubated with the dye at 200 nM for 5 min at 37°C before fixation.

Colocalization of GFP-M. tuberculosis with the markers was quantified by counting at least 200 phagosomes in preparations of two different donors.

Transferrin and dextran uptake

Cells were deprived of transferrin by incubation in serum-free RPMI 1640 for 2 h at 37°C, washed in RPMI 1640, and incubated for 1 h at 4°C or 37°C with Texas Red (TR)-conjugated transferrin (50 µg/ml; Molecular Probes) in an excess of BSA (2 mg/ml) to saturate nonspecific endocytosis. Cells were washed twice in cold RPMI 1640 and incubated for 5 min at room temperature with (25 mM citric acid, 24.5 mM sodium citrate, 280 mM sucrose, pH 4.6) to remove extracellular transferrin. After 0–2 h chase with excess unlabeled transferrin (5 mg/ml + 2 mg/ml BSA), cells were fixed PBS-PFA and observed by confocal microscopy or flow cytometry. FITC-conjugated dextran (Sigma-Aldrich, St. Louis, MO) was pulsed at 1 mg/ml for 1 h at 4°C or 37°C. Cells were washed with cold PBS and fixed with PBS-PFA before flow cytometry analysis.

Cytokine detection in supernatants

DCs were left uninfected, incubated with heat-killed M. tuberculosis, or infected with live mycobacteria as described above and cultured for 48 h. Then, 10⁵ DCs were cultured for 48 h with 10⁶ autologous T lymphocytes enriched as reported (36). IL-2, IL-4, IL-5, IL-6, and IFN- levels in culture supernatants were then assessed by ELISA according to the manufacturer’s recommendations (R&D Systems). As controls, supernatants were collected from cultures of noninfected or M. tuberculosis-infected DCs alone, DCs alone incubated with heat-killed M. tuberculosis, DCs mixed with T lymphocytes without any stimulus, and T lymphocytes that were incubated or not with 20 µg/ml purified protein derivative (PPD; Sigma-Aldrich) with or without added DCs.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Human DCs do not support intracellular replication of M. tuberculosis H37Rv

DCs derived from monocytes cultured with GM-CSF and IL-4 did not support intracellular replication of M. tuberculosis H37Rv (Fig. 1A). The bacterial load was slightly decreased (0.3- to 0.4-log reduction in CFUs) between days 0 and 7, a value unlikely to reflect active killing of bacteria by infected cells. In contrast, Ms derived from the same monocytes cultured with M-CSF, permitted intracellular replication of bacteria with a 26- to 28-h doubling time. This observation was confirmed using DCs prepared from monocytes treated with GM-CSF and IL-13 (35). Again, mycobacteria persisted at almost constant levels in these cells, without any obvious replication (Fig. 1B). Because GM-CSF has previously been reported to restrict mycobacterial growth in monocyte-derived Ms (37), we ascertained that our findings in DCs were not due to the presence of the cytokine per se. To this end, we compared M. tuberculosis growth in GM-CSF-differentiated and in M-CSF-differentiated Ms in the presence of either M-CSF or GM-CSF during the infection period. The three culture conditions allowed mycobacterial growth at almost identical rates (Fig. 1C). Thus, it is very unlikely that the constrained survival of M. tuberculosis observed in DCs was due to the presence of GM-CSF per se in the culture medium.

View larger version (20K): [in this window] [in a new window]   FIGURE 1. DCs restrain M. tuberculosis H37Rv replication in vitro. A, Ms () were obtained from M-CSF-induced monocytes; DCs were obtained from monocytes cultured with GM-CSF (GM)/IL-4; cytokines were left in the DC culture medium supplemented with 10% human AB serum throughout the course of infection () or discontinued (•) before infection; CFU numbers were determined at the indicated time points. B, Ms () were obtained as in A; DCs were obtained from monocytes cultured with GM-CSF/IL-13 (); cytokines were left in the culture medium throughout the course of infection. C, Ms were obtained as in A ( and •) or from GM-CSF-treated monocytes (); cytokines were maintained throughout the course of infection (• and ) or M-CSF was replaced by GM-CSF (•). D, CD1a and CD14 expression by 48-h-infected DCs when GM-CSF/IL-4 was either kept in the culture (left) or discontinued (right). Data in A–C are mean values (±SD) from triplicate experiments using monocyte-derived Ms and DCs from three different donors. Data presented in D are from one representative experiment of three with as many different donors. Comparable results were obtained whether cells were cultured and infected in the presence of human AB serum or FCS (data not shown). w/o, Without.

In our experiments, as reported (39), infection often resulted in a preliminary stationary-like 48- to 72-h phase during which the net bacterial load remained relatively constant, but after which growth either started (in Ms) or not (in DCs). This initial stage might reflect the time required for the microbe to arrange its intracellular niche. Thus, we investigated comparatively in Ms and DCs whether the contrasting behavior of M. tuberculosis could be explained, at least in part, by the different intracellular compartments available to the bacillus in the two cell types.

The maturation of the M. tuberculosis vacuole is arrested in DCs

In Ms, based on studies showing that mycobacterial phagosomes fail to acidify and to fuse with host cell late endosomes and lysosomes, pathogenic mycobacteria are thought to reside in a mildly acidic compartment that is arrested at an early stage of the endocytic pathway (19). Confocal microscopy examination of M. tuberculosis-infected cells showed that most mycobacterial vacuoles failed to acidify in DCs (Fig. 2A) as in Ms (data not shown), as attested by lack of accumulation of the acid tropic dye LysoTracker (Molecular Probes) in vacuoles for up to 5 days after initial infection. PFA-killed M. tuberculosis, used as a control, were readily transported within 24 h to acidic (LysoTracker-positive) phagolysosomes in both DCs (Fig. 2A) and Ms (data not shown). As reported in Ms (20), the lack of vacuole acidification in DCs was associated with the absence of H⁺ATPase onto the vacuolar membrane, whereas H⁺ATPase was abundant on phagolysosomes containing PFA-killed M. tuberculosis (data not shown). Mycobacterial vacuoles also lacked the late endosome-specific marker ciM6PR in both Ms and DCs (data not shown).

View larger version (15K): [in this window] [in a new window]   FIGURE 2. The maturation of the M. tuberculosis vacuole is arrested in DCs. A, DCs infected for 48 h with live (top) or PFA-killed GFP-M. tuberculosis (Mtb) (bottom) were stained with the acid-tropic dye LysoTracker. B, DCs (top) or Ms (bottom) infected for 48 h with live GFP-M. tuberculosis were stained for the coronin 1-like TACO. Data are representative of three (A) and six (B) experiments performed on monocyte-derived DCs and Ms from as many different donors. The graphs indicate the percentages of TACO-positive phagosomes assessed by counting >200 phagosomes in preparations of one representative donor of two examined. No significant difference was observed between infection days 2 and 5. In Ms, TACO was also detected at the plasma membrane, but due to the strong staining on phagosomes the signal had to be reduced. p.i., Postinfection.

M. tuberculosis vacuoles have no access to exogenous material in DCs

Survival of mycobacteria within Ms is thought to rely, at least in part, on continuous access of the microbes to extracellular nutrients through permanent fusion events of the bacterial phagosome with host cell endosomes (19). We thus reasoned that constrained survival of M. tuberculosis inside DCs could be due to reduced access of the mycobacterial vacuole to endosomes. Uptake of the fluid phase marker dextran was almost abolished in infected DCs compared with uninfected cells, whereas it remained constant in infected Ms (Fig. 3A). This results most likely from DC maturation upon M. tuberculosis infection. To assess whether receptor-mediated endocytosis was also diminished in infected DCs, we pulsed the cells with TR-labeled transferrin. The conditions of transferrin uptake used here allowed staining of the recycling compartment only, because pulsed TR-transferrin was chasable within 1 h by an excess unlabeled transferrin (data not shown). As for dextran, transferrin uptake was strikingly diminished in infected DCs but not in Ms (Fig. 3B). Consequently, transferrin could not reach M. tuberculosis vacuoles in DCs, even after up to a 2-h pulse (Fig. 3B). These results suggest that M. tuberculosis vacuoles have no access to recycling endosomes in DCs only. To strengthen this finding, we stained infected cells with the recycling endosome-specific small GTPase Rab11. As shown in Fig. 3C, 45–65% of phagosomes retained GTPase Rab11 in Ms over the 5-day infection period, whereas Rab11 was detected on only 10–15% of vacuoles in DCs already at 3 h postinfection. Rab11 is present on recycling vesicles and the trans-Golgi network (TGN) in various cell types (41), including Ms (42), and it has once been reported to be present on M. bovis BCG phagosomes in murine Ms (24). In our experiments, it is unlikely that Rab11 enrichment on mycobacterial phagosomes in Ms reflected communication of the vacuoles with the TGN, since confocal microscopy analysis clearly indicated that M. tuberculosis vacuoles were devoid of TGN-specific markers Rab6 and Golgin97 (data not shown). Thus, it is rather likely that the presence of Rab11 on phagosomes in Ms but not in DCs reflects differential access of the vacuoles to recycling endosomes in the two cell types.

View larger version (30K): [in this window] [in a new window]   FIGURE 3. Mycobacterial vacuoles in DCs are inaccessible to endosomes. Ms or DCs infected for 48 h with M. tuberculosis (A) or GFP-M. tuberculosis (B and C) were analyzed by flow cytometry (A) or confocal microscopy (B and C) for uptake of FITC-conjugated dextran (A) or TR-transferrin (B), or Rab11 staining (C). A, Dashed lines, controls at 4°C; bold lines, infected cells; thin lines, uninfected cells. C, Percentages of Rab11-positive phagosomes assessed by counting >200 phagosomes in preparations of one donor of two examined. Confocal microscopy images are representative of two (A and B) and four (C) independent experiments performed on monocyte-derived DCs from as many different donors. No significant difference was observed between infection days 2 and 5. p.i., Postinfection.

We next examined the possible communication between mycobacterial phagosomes and the host cell biosynthetic pathway, which could allow intracellular mycobacteria to access additional nutrients including host cell lipids. We found that in infected Ms, 30–40% and 55% of M. tuberculosis phagosomes stained for the endoplasmic reticulum (ER)-specific proteins calnexin and 78-kDa glucose-regulated protein (Grp78/BiP), respectively, during a 5-day infection period. In contrast, only 10% of M. tuberculosis vacuoles in DCs were positive for these markers 48 h after phagocytosis (Fig. 4, A and B). As controls, phagolysosomes containing PFA-killed M. tuberculosis did not stain for calnexin in either Ms or DCs (data not shown). These data suggest that the mycobacterial vacuole remains in continuous communication with the ER in Ms but not in DCs.

View larger version (33K): [in this window] [in a new window]   FIGURE 4. Intracellular M. tuberculosis communicates with the cell biosynthetic pathway in Ms but not in DCs. Ms and DCs were infected for 48 h with GFP-M. tuberculosis (Mtb) and stained for the endoplasmic reticulum-specific markers calnexin and Grp78/BiP (A and B), and the fusion factor NSF (C). The graphs indicate percentages of calnexin-, Grp78/BiP-, or NSF-positive phagosomes, respectively, assessed by counting >200 phagosomes in preparations of one donor of two examined. Confocal microscopy images are representative of four (A and B) and three (C) independent experiments performed on monocyte-derived DCs and Ms from as many different donors. No significant difference was observed between infection days 2 and 5. C, NSF was detected in M cytosol, but due to the strong staining on the phagosomes, the signal had to be reduced. p.i., Postinfection.

M. tuberculosis-infected DCs present mycobacterial Ags to T lymphocytes

Finally, we examined whether the particular location of mycobacteria in DCs could perturb their ability to present mycobacterial Ags to T lymphocytes (5). Thus, we incubated M. tuberculosis-infected DCs with autologous T lymphocytes from donors known to have been previously sensitized against M. tuberculosis by M. bovis BCG vaccination, which is mandatory in France to assess their capacity to produce IL-2, IL-6, IFN-, and IL-5. Under these conditions, the T lymphocytes were stimulated to produce cytokines in culture supernatants, especially IL-2 and IFN- and to a lesser degree IL-5 and IL-6, to levels comparable with or greater than those of noninfected DCs pulsed with PPD from M. tuberculosis H37Rv or with heat-killed bacteria (Fig. 5). Infected DCs alone as well as T cells alone were unable to produce IL-2 (Fig. 5), and IL-4 was undetectable under any of the conditions used here (data not shown).

View larger version (15K): [in this window] [in a new window]   FIGURE 5. M. tuberculosis (Mtb)-infected DCs stimulate autologous T lymphocytes (T) to produce cytokines. DCs infected 2 days previously were cultured for 48 h with autologous T lymphocytes, and IL-2, IL-5, IL-6, and IFN- were then assessed in culture supernatants. As controls, T lymphocytes were cultured alone or in the presence of PPD, noninfected DCs and T lymphocytes were incubated or not with PPD, or DCs were mock-infected with heat-killed (hk) mycobacteria. Data are representative of three experiments corresponding to as many different donors.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

Our data are in line with the report by Jiao et al. (15), who found that M. bovis BCG persists but does not replicate in splenic DCs of experimentally infected mice. A similar discrepancy between DCs and Ms has also been reported for other intracellular bacteria. For instance, Listeria monocytogenes does not replicate in murine DCs, in vitro in human DCs (44) or in vivo in rats (45). In parallel with our observation, Salmonella typhimurium does not replicate but persists over time in murine DCs (46). Furthermore, it has been shown that several S. typhimurium genes, such as phoP, essential for survival and replication of the bacterium in Ms, are dispensable in DCs, suggesting that the intracellular compartment occupied by the microbe differs in the two cell types (46).

The different behavior of M. tuberculosis in Ms and DCs prompted us to characterize the vacuole occupied by the bacillus in the two cell types. To survive inside Ms, pathogenic mycobacteria have developed mechanisms to resist intracellular degradation and to keep access to essential nutrients by intercepting the host cell recycling pathway (19, 27, 28). Our data that mycobacterial phagosomes stain for Rab11 in Ms is in line with such assumption. Indeed, Rab11 GTPase localizes to transferrin receptor-containing pericentriolar recycling compartments in a variety of polarized cells (47). Rab11 also localizes to a recycling compartment in mouse Ms (42), even though the cells lack a morphologically distinct pericentriolar recycling compartment. It is also present on the TGN, but we have shown that M. tuberculosis phagosomes do not communicate with the TGN since they failed to accumulate TGN-specific markers Rab6 and Golgin97. On the contrary, Rab11 was detected in very few mycobacterial vacuoles in DCs, suggesting that the vacuoles have limited access to recycling vesicles in these cells. Indeed, use of labeled transferrin allowed us to demonstrate that transferrin cannot reach the mycobacterial compartment in infected DCs. Such reduced endocytosis, which is mediated by the transferrin receptor (48), most likely results from DC maturation (49). In our experiments, M. tuberculosis infection led to maturation of DCs, as illustrated by up-regulation of surface CD83 and other markers, including MHC-II and CD86 (data not shown). Dextran uptake, which is mediated both via the mannose receptor and macropinocytosis (50), was also strongly diminished in infected DCs. It is likely that the global maturation-induced reduction in endocytic processes impairs M. tuberculosis to access exogenous nutrients, and thus to impair replication in DCs.

Although communication between mycobacterial phagosomes and M recycling endosomes has been extensively studied, accessibility of the vacuoles to the cell biosynthetic pathway has been suggested only once in M. avium-infected murine Ms (51). We found that a significant proportion of mycobacterial phagosomes stained strongly for the ER-specific markers calnexin and Grp78/BiP in Ms only. Whether this results from a specific mycobacterial ER-targeting strategy still remains to be elucidated. A more probable explanation relies on an attractive model of membrane homeostasis recently proposed by Gagnon et al. (52), which suggests that ER-derived material could interact directly with phagosomes to keep particles in closed compartments while the plasma membrane engaged in phagosome formation recycles back to the cell surface to maintain a stable cell size. Interestingly, according to this model, infected mature DCs that no longer endocytose and phagocytose would not require ER-derived material to accumulate on bacterial vacuoles, which is what we have observed.

The overall reduced fusogenicity of M. tuberculosis vacuoles in DCs consistently correlated with the paucity of this compartment in the ATPase NSF, a factor involved in a broad range of intracellular membrane fusion events (43). Several intracellular pathogens reside in NSF-rich vacuoles, indicating that they represent dynamic compartments involved in permanent fusion and fission events with other intracellular organelles. Two such examples are S. typhimurium, which actively recruits NSF on the phagosomal membrane in murine M-like J774 cells as a specific means to promote phagosomal fusion with early endosomes (53) and M. bovis BCG phagosomes in J774 cells (32).

Finally, our data suggest that the unique location occupied by M. tuberculosis within DCs does not disturb their T lymphocyte-stimulating function, inasmuch as infected DCs had the ability to activate T lymphocytes to produce cytokines, especially IFN-. However, one cannot rule out that lymphocytes were then activated by DCs that had ingested material containing mycobacterial Ags, including apoptotic bodies and exosomes (54), in addition to, or instead of, directly infected DCs.

The different behavior of M. tuberculosis in Ms and in DCs may reflect differences in the receptors involved in bacterial uptake by the two cell types. For example, DCs have surface receptors such as the recently identified DC-specific ICAM3 grabbing nonintegrin (DC-SIGN/CD209), that are not expressed on most M types, and that are dedicated to Ag uptake (55). We have recently demonstrated that M. tuberculosis enters human DCs after binding to DC-SIGN (56). By contrast, the complement receptor type 3 and the mannose receptor, which are involved in the phagocytosis of mycobacteria by Ms, appeared to play a minor role, if any, in mycobacterial binding to DCs. Intracellular route of ingested particles mostly differs depending on the receptors engaged in particle ligation and phagocytosis, and the trafficking of DC-SIGN-bound mycobacteria is now being investigated. Recent reports have also shown profound differences in the phagosome biology of Ms relative to DCs. For example, DCs but not Ms can present exogenous Ags to CD8⁺ T lymphocytes via a cytosol-dependent pathway involving an as yet unidentified phagosome-to-cytosol transporter (57).

Taken together, our findings might be interpreted in two different but not exclusive ways. One might hypothesize that DCs have evolved specific mechanisms for priming T lymphocytes after homing from the lungs to lymph nodes, while maintaining mycobacteria alive in vacuoles, reminiscent of the retention compartment reported in a mouse DC line (58, 59). Indeed, we and others have shown that mycobacterial Ag presentation by MHC molecules is far more efficient when bacteria are viable (31). This might allow T lymphocytes to respond to Ags produced in replicating mycobacterium-infected cells, such as alveolar Ms. On the other hand, this might offer the possibility to the microbe to use DCs as a vehicle to spread inside the host and reach the lymphoid tissues. In our experiments, M. tuberculosis-infected DCs exhibited a migratory phenotype (CCR5^-, CXCR4⁺) (L. Tailleux, O. Neyrolles, J. L. Herrman, P. H. Lagrange, and J. C. Gluckman, unpublished data) while maintaining a relatively constant bacterial load for up to 7 days, which is more than enough for DCs to migrate from the periphery to secondary lymphoid organs (60). Similar observations have been made in M. tuberculosis-infected murine DCs (7). Recent reports suggest that various pathogens can exploit the migratory properties of mature DCs to disseminate within the host. For example, Leishmania spp. have been shown to persist within DCs in lymph nodes, suggesting that DCs are impaired in their ability to kill this pathogen, which can then manipulate DCs for its own invasion strategy (61). In the case of mycobacteria, this might explain such clinical phenomena as mediastinal lymphadenitis, usually associated with primary M. tuberculosis infections. A spread to local lymph nodes might also account for persistence of the pathogen and chronic stimulation of the immune system. Whether M. tuberculosis is in a dormant-like state in DCs still remains to be firmly defined. These possibilities are currently being investigated using in vitro-infected DCs and lymph node biopsies from patients with tuberculosis.

	Acknowledgments

 
We thank R. Steinman (The Rockefeller Institute, New York, NY), D. Young (Imperial College, London, U.K.), B. Marshall (Southampton University Hospital, Southampton, U.K.), V. Nagaraja (Indian Institute of Science, Bangalore, India), O. Schwartz and L. Quintana-Murci (Institut Pasteur, Paris, France), and Alan Murray (Institute of Veterinary, Animal and Biomedical Sciences, Massay University, Palmerston North, New Zealand) for carefully reading the manuscript and helpful discussions.

We thank Graham Stewart (Imperial College) and Jean Pieters (Basel Institute for Immunology, Basel, Switzerland) for providing pEGFP and anti-TACO Abs, respectively. We are indebted to Schering-Plough for the generous gift of recombinant GM-CSF and IL-4. We thank Michel Schmid (Hôpital Saint-Louis, Paris, France) for his kind help in setting up confocal microscopy analysis.

	Footnotes

 
¹ This work was supported by the Agence Nationale de Recherche sur le SIDA, the Association de Recherche Contre le Cancer, the Comité de Paris de la Ligue Nationale Contre le Cancer, the Association pour la Recherche sur les Déficits Immunitaires Viro-Induits, and Association Claude Bernard (Paris). L.T. is a fellow of the Agence Nationale de Recherche sur le SIDA and Fondation pour la Recherche Médicale, and O.N. is a fellow of the Fondation pour la Recherche Médicale.

² L.T. and O.N. contributed equally to this work.

³ Current address: Institut Pasteur, Unité de Génétique Mycobactérienne, Paris, France.

⁴ Address correspondence and reprint requests to Dr. Jean-Louis Herrmann, Service de Microbiologie, Hôpital Saint-Louis, 1 avenue C. Vellefaux, 75010 Paris, France. E-mail address: jean-louis.herrmann{at}sls.ap-hop-paris.fr

⁵ Abbreviations used in this paper: M, macrophage; DCs, dendritic cells; BCG, bacillus Calmette-Guérin; ciM6PR, cation-independent mannose 6-phosphate receptor; TACO, tryptophan-alanine-rich coat protein; NSF, N-ethylmaleimide-sensitive factor; GFP, green-fluorescent protein; PFA, paraformaldehyde; PBS-PFA, PBS-4% PFA; TR, Texas Red; PPD, purified protein derivative; TGN, trans-Golgi network; ER, endoplasmic reticulum; Grp78/BiP, 78-kDa glucose-regulated protein.

Received for publication June 27, 2002. Accepted for publication December 2, 2002.

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