View larger version (33K): [in this window] [in a new window] [Download PPT slide]   Figure 2. PRAT4A is required for TLR responses in macrophages. (A) Shaded histograms show cell-surface expression of the indicated markers on BM-macrophages from PRAT4A+/– or PRAT4A–/– mice. Open histograms show control staining with the second reagent alone. (B) Bar graphs show cytokine production by BM-macrophages in response to a variety of TLR ligands (1 and 10 ng/ml lipid A, 100 ng/ml PCSK, 100 ng/ml FSL-1, 100 nM CpG-B, 150 µM loxoribine, and 100 µg/ml poly(I:C)). (C) Bar graphs show real-time RT-PCR analyses for mRNA encoding IFN-β, the amount of which was normalized by that of mRNA for β-actin. BM-macrophages were stimulated with the indicated TLR ligands and RNA was collected 2 (lipid A) or 5 (poly(I:C)) h after stimulation, respectively. Data in B and C represent the SD.

View larger version (52K): [in this window] [in a new window] [Download PPT slide]   Figure 3. PRAT4A is required for TLR responses in B lymphocytes. (A) Shaded histograms show cell-surface expression of the indicated markers on B220-positive splenic B cells. Open histograms show control staining with the second reagent alone. (B) Dot plots show cell-surface expression of IgM and IgD on splenocytes. (C) Proliferation of enriched B cells stimulated with a variety of stimulation (100 and 1,000 ng/ml lipid A, 1,000 ng/ml PCSK, 1,000 ng/ml FSL-1, 500 nM CpG-B, 100 µg/ml poly(I:C), 1 µg/ml anti-RP105 antibody, 1 µg/ml anti-IgM antibody plus 2.25 µg/ml anti-CD40 antibody). Splenic B cells were enriched from BM chimeric mice and stimulated for 3 d. 1 µCi [3H]thymidine was pulsed for the last 6 h, and the incorporated thymidine was counted by a scintillation counter. (D) Shaded histograms show CD86 up-regulation on B cells stimulated with the indicated reagents. The concentration used was as described in C. Open histograms show control staining with the second reagent alone.

View larger version (76K): [in this window] [in a new window] [Download PPT slide]   Figure 4. PRAT4A resides in the ER and is required for TLR4 protein maturation and TLR9 relocation. (A) PRAT4A-GFP was expressed in HEK293 cells together with a marker locating ER (a), the Golgi apparatus (b), or lysosome (c). PRAT4A-GFP (green) and the markers (red) were visualized by confocal microscopy. (B) TLR4-GFP and PRAT4A-FlagHis were expressed in HEK293 cells, and PRAT4A was stained with anti-Flag mAb. TLR4-GFP (green) and PRAT4A-FlagHis (red) were visualized by confocal microscopy. (C) Ba/F3 cells expressing TLR4–Flag/MD-2 were transduced with a control vector (lanes 1–3) or with a vector encoding shPRAT4A (lanes 4–6). Cells were subjected to immunoprecipitation with anti-Flag antibody, followed by treatment with buffer (N), endoH, or N-glycanase (N-Gly), as indicated in the figure. Samples were further subjected to SDS-PAGE and immunoprobing with anti-TLR4 mAb. Molecular masses are shown in kilodaltons. (D) B cell lymphoma M12 cells expressing TLR9-GFP plus a control vector (left) or TLR9-GFP plus shPRAT4A (right) were stimulated with medium (a and e) or 1 µM CpG-B for 2 h (b–d and f–h). Cells were counterstained with markers for ER (a, b, e, and f) or lysosome (c and g) and visualized by confocal microscopy. (bottom) CpG-B conjugated with 1 µM rhodamine was used for stimulation, and its distribution was determined in d and h. Bars, 5 µm.

TLR9 is unable to traffic to lysosomes upon ligand stimulation in PRAT4A knockdown cells
All TLR9-dependent responses were completely abolished in BM-DCs, BM-macrophages, and B cells from mice lacking PRAT4A (Figs. 1–3). Because TLR9 resides in the ER, N-linked oligosaccharides remain immature and are all cleaved by endoH treatment (15, 16). TLR9 may differ from cell-surface TLRs in a way requiring PRAT4A. To address a molecular mechanism by which PRAT4A controls TLR9, we first studied physical association between these two molecules. We were able to detect PRAT4A coprecipitation with TLR9, whereas coprecipitation of TLR9-GFP with PRAT4A-hemagglutinin (HA) was very weak (Fig. S3 A, available at http://www.jem.org/cgi/content/full/jem.20071132/DC1). TLR9-GFP and short hairpin RNA (shRNA) targeting PRAT4A (shPRAT4A) were both expressed in the M12 B cell line. A 75% silencing effect was confirmed by real-time RT-PCR (Fig. S3 B). The TLR9-GFP protein in cells expressing shPRAT4A was still detectable by flow cytometry (Fig. S3 C). We studied the subcellular distribution of TLR9 in the absence of CpG-B stimulation. Given that TLR9 is an ER-resident protein, TLR9-GFP was compared with an ER marker. Colocalization of TLR9-GFP with an ER marker was not affected by shPRAT4A (Fig. 4 D, a and e). Upon CpG-B stimulation, TLR9 was reported to redistribute from the ER to CpG-B DNA–containing lysosomes (15, 16). To see if PRAT4A was required for ligand-induced TLR9 trafficking, M12 cells expressing TLR9-GFP were stimulated with CpG-B, and the subcellular distribution of TLR9-GFP was studied (Fig. 4 D). TLR9-GFP in control cells relocated out of the ER after 2 h of stimulation with CpG-B, whereas TLR9-GFP in M12 cells expressing shPRAT4A remained colocalized with an ER marker (Fig. 4 D, compare b with f). Relocated TLR9 in control M12 cells was colocalized with a lysosome marker and with internalized CpG-B conjugated with rhodamine (Fig. 4 D, c and d), indicating the egress of TLR9 from the ER and its ligand–receptor interaction in lysosomes. In sharp contrast, TLR9-GFP in M12 cells expressing shPRAT4A remained colocalized with an ER marker but not with a lysosome marker or CpG-B–rhodamine (Fig. 4 D, f–h). shPRAT4A did not influence internalization of CpG-B or its trafficking to lyososmes (Fig. 4 D, d and h). These results clearly demonstrate a requirement for PRAT4A in ligand-induced relocation of TLR9 from the ER to lysosomes. Collectively with the results regarding TLR4 and TLR1, TLRs seem to be unable to mature in the ER or to egress from the ER in the absence of PRAT4A.

PRAT4A-independent signaling in response to lipid A or a lipopeptide
Some PRAT4A-independent responses were seen in response to LPS or lipopeptides, and this was particularly the case with BM-DCs (Fig. 1). Therefore, we studied signaling events upon stimulation with lipid A, PCSK, or CpG-B (Fig. 5 A). Lipid A–induced IB degradation was apparently inhibited, whereas IFN regulatory factor (IRF) 3 and mitogen-activated protein kinase phosphorylation were partially impaired in PRAT4A^–/– BM-DCs. After PCSK stimulation, phosphorylation of extracellular signal-regulated kinase 1/2 and p38 was apparently delayed, and c-Jun N-terminal kinase 1/2 phosphorylation was impaired in PRAT4A^–/– BM-DCs. CpG-B was distinct from these two TLR ligands in that all of the signaling pathways studied were completely abolished in PRAT4A^–/– BM-DCs. TLR9 was completely dependent on PRAT4A, whereas TLR4 and TLR2 were still able to signal in the absence of PRAT4A. PRAT4A-independent lipid A responses were most obvious in up-regulation of the CD86 co-stimulatory molecule. BM-DCs were induced from BM chimeric mice and stimulated with lipid A, lipopeptides, CpG-B, and poly(I:C). Poly(I:C) and lipid A were most potent in inducing CD86 up-regulation, and no alteration was seen between PRAT4A^+/– or PRAT4A^–/– cells (Fig. 5 B). A lipopeptide (FSL-1) weakly induced CD86 up-regulation in both PRAT4A^+/– and PRAT4A^–/– mice. The other lipopeptides, PCSK and CpG, weakly induced CD86 only in PRAT4A^+/– cells.

View larger version (81K): [in this window] [in a new window] [Download PPT slide]   Figure 5. PRAT4A-independent responses in BM-DCs. (A) BM-DCs from BM chimeric mice were stimulated with lipid A, PCSK, or CpG-B, as indicated in the figure. After the indicated periods of time, cells were lysed and subjected to SDS-PAGE, Western blotting, and immunoprobing with the indicated antibodies. (B) CD86 on BM-DCs from BM chimeric mice was stained 48 h after stimulation with the indicated TLR ligands. Shaded histograms show staining with the second reagent alone. Histograms with continuous or dashed lines show CD86 staining of BM-DCs cultured with TLR ligands or medium, respectively.

To determine the requirement for the C-terminal sequence similar to the ER retention signal, we next conducted retrovirus-mediated complementation of PRAT4A^–/– DCs. PRAT4A^–/– BM cells that had been treated with 5-fluorouracil (5-FU) were transduced with retroviral vector encoding PRAT4A or its deletion mutants (Fig. S5 A, available at http://www.jem.org/cgi/content/full/jem.20071132/DC1). After DC induction with GM-CSF, expression of PRAT4A was examined by immunoprobing of the cell lysate with anti-PRAT4A polyclonal antibody. We were able to detect endogenous PRAT4A but not the transduced PRAT4A (unpublished data). Expression of the transduced PRAT4A seemed to be much lower than that of endogenous PRAT4A. We observed that the flag-tagged PRAT4A was secreted into the culture supernatant (unpublished data). We therefore conducted immunoprecipitation and immunoprobing of the culture supernatant with antibody to the flag epitope and were able to confirm expression of transduced PRAT4A (Fig. S5 B). We then looked at cell-surface expression of TLR2 and TLR4. DCs induced from 5-FU–treated BM were distinct from conventional BM-DCs in that cell-surface TLR4 was too low to detect by flow cytometry (unpublished data). Instead, we were able to detect cell-surface TLR2 on PRAT4^+/+ DCs but not on PRAT4A^–/– DCs (Fig. S5 C). Overexpression of PRAT4A complementary DNA partially but apparently up-regulated cell-surface TLR2 (Fig. S5 C). Complementation was also seen in cytokine production against TLR ligands (Fig. S5, D and E). Only the partial complementation seen in cell-surface expression of TLR2, TLR4-dependent production of IL-12, and TLR9-dependent IL-6 production was probably caused by low expression of the transduced PRAT4A. PRAT4A mutant lacking the putative ER retention signal PDEL (Del-1) or the C-terminal 19 aa (Del-2) were both as effective as the full-length PRAT4A in complementing cell-surface expression of TLR2 and TLR4/9 responses (Fig. S5, C–E). No apparent difference in complementation with the PRAT4A mutant was observed between TLR4 and TLR9 responses and between MyD88-dependent IL-12 production and TRIF-dependent RANTES production.

PRAT4A is required for cytokine production against bacteria
The results above (Figs. 1–5) have revealed that PRAT4A influences multiple TLR responses in vitro by regulating TLR maturation in the ER and/or the egress from the ER. Bacteria such as Escherichia coli have many TLR ligands, and immune cells such as BM-DCs, macrophages, or B cells express multiple TLRs. Given the apparent importance of PRAT4A for controlling the positioning and densities of multiple TLRs, PRAT4A^–/– immune cells are likely to be compromised with respect to bacterial responses. To address this issue, heat-killed E.coli or M. tuberculosis was used for stimulating immune cells in vitro and in vivo. Heat-killed E. coli was effective in inducing the production of IL-6, TNF-, IL-12, and RANTES in wild-type BM-DCs. All cytokine production was significantly impaired in PRAT4A^–/– BM-DCs (Fig. 6 A). In sharp contrast to cytokine production, up-regulation of the CD86 co-stimulatory molecule was unaffected in PRAT4A^–/– DCs (Fig. 6 B). In response to M. tuberculosis, cytokine production, particularly of IL-6 and TNF-, was impaired in PRAT4A^–/– BM-DCs (Fig. S6 A, available at http://www.jem.org/cgi/content/full/jem.20071132/DC1), whereas CD86 up-regulation was normal (Fig. S6 B). BM chimeric mice were next stimulated with heat-killed E. coli, and cytokine concentrations in the circulation were measured 3 h after injection. Heat-killed E. coli induced production of IL-12, IL-6, and RANTES in vivo, and all of the production was significantly impaired in PRAT4A^–/– mice (Fig. 6 C). Interestingly, IL-12 production against heat-killed bacteria in vivo was more severely impaired than that by BM-DCs (Fig. 6, A and C). An important role for macrophages was recently reported in in vivo IL-12 production in response bacteria (11). Given that PRAT4A^–/– macrophages were more severely impaired than PRAT4A^–/– BM-DCs in cytokine production against TLR ligands (Figs. 1 and Figs.2), in vivo IL-12 production in response to heat-killed E. coli might be mainly contributed by macrophages.

View larger version (31K): [in this window] [in a new window] [Download PPT slide]   Figure 6. PRAT4A is required for cytokine production in response to heat-killed E. coli. (A) BM-DCs from BM chimeric mice were stimulated with heat-killed E. coli, as indicated in the figure. After 24 h of culture, concentrations of cytokines in the supernatant were determined by ELISA. Data represent the SD. *, P < 0.05. (B) CD86 on BM-DCs from BM chimeric mice was stained 48 h after stimulation with heat-killed E. coli. Shaded histograms show staining with the second reagent alone. Histograms with solid or dashed lines show CD86 staining of BM-DCs cultured with heat-killed E. coli or medium, respectively. (C) BM chimeric mice (n = 5) were injected with heat-killed E. coli (3.5 x 108 cells per mouse) and bled 3 h after injection. Serum cytokines were measured by ELISA. Data represent the SD. *, P < 0.05.

View larger version (36K): [in this window] [in a new window] [Download PPT slide]   Figure 7. Th1 responses are impaired in PRAT4A–/– mice. Cells from draining popliteal lymph nodes were collected from mice 8 d after immunization (hind legs) with OVA in CFA. (A) The proliferation of antigen-specific lymph node cells from PRAT4A+/– or PRAPT4A–/– BM chimeric mice was measured by culturing these cells with OVA for 72 h. (B) IFN- production was determined by ELISA from supernatants of antigen-stimulated lymph node cells from PRAT4A+/– or PRAT4A–/– BM chimeric mice. Data are means + SD from each mouse, and the results of three independent mice per group are shown. Similar results were obtained in two independent experiments. (C) Serum was collected before (day 0) and after (day 8) immunization with OVA plus CFA, and the titers of OVA-specific IgM, IgG2a/c, and IgG2b were determined by ELISA. Data are means + SD from three mice per group. Similar results were obtained in two independent experiments. *, P < 0.01.

View larger version (16K): [in this window] [in a new window] [Download PPT slide]   Figure 8. PRAT4A–/– BM chimeric mice are resistant to LPS-induced sepsis. (A) PRAT4A–/– (n = 10), PRAT4A+/– (n = 5), and PRAT4A+/+ (n = 5) BM chimeric mice were administered with 400–500 µg LPS intraperitoneally, and the mortality was shown as the percentage of survival. (B) Blood samples from PRAT4A+/– (n = 6) and PRAT4A–/– (n = 6) mice were collected from the vena cava at 0 (no treatment), 1, 3, and 6 h after injection of a lethal dose of LPS (500 µg per mouse). The concentrations of TNF-, IL-6, IL-12, and RANTES were determined by ELISA. Data represent the SD. *, P < 0.01.

	DISCUSSION

Top ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS REFERENCES

 
Successful targeting of the PRAT4A gene revealed that the corresponding protein is required for many TLR-dependent functions and has the potential for coordinating innate and adaptive immune responses. Characterization of the knockout mice was informative about many aspects of TLR maturation, as well as trafficking within and display on immune cells. Moreover, we were able to categorize particular cellular responses to TLR ligands according to their dependence on PRAT4A.

PRAT4A is required for cell-surface expression of the Toll family of receptors and a related molecule, RP105. No abnormalities were found in cell-surface expression of non-TLR molecules, including CD11c, CD11b, CD14, B220, MHC class I, CD19, IgM, IgD, and others in PRAT4A^–/– immune cells. Importantly, PRAT4A was not required for antigen receptor expression and function, because PRAT4A^–/– B cells developed normally and responded to BCR-mediated signaling (Fig. 3 B). In this regard, PRAT4A is distinct from gp96, which was reported to chaperone Ig (17). Although gp96 is a general chaperone, PRAT4A seems to be more dedicated to TLRs in immune cells. Immature glycosylation of cell-surface TLRs such as TLR1 and TLR4 in PRAT4A knockdown cells suggests an important role for PRAT4A in TLR protein maturation in the ER (Figs. 4 C and S2 C) (12). Consequently, TLR2/4 responses were impaired in PRAT4A^–/– BM-DCs, macrophages, and B cells (Figs. 1–3).

PRAT4A is also required for intracellular nucleic acid–sensing TLR7/9. ER-resident TLR9 does not require maturation of N-linked oligosaccharide in the Golgi apparatus. Nonetheless, TLR9 was unable to traffic to the endosome/lysosome during ligand stimulation in PRAT4A knockdown cells (Fig. 4 D). Given that the TLR9 ligand CpG is sequestered to lysosomes, TLR9 is unlikely to interact with its ligand DNA in the absence of PRAT4A. As a result, TLR9 responses and signaling were completely abolished (Figs. 1–5). TLR7 responses were impaired as much as TLR9 responses in PRAT4A^–/– BM-DCs, BM-macrophages, and splenic B cells (Figs. 1–3). Although TLR7 has not been reported to relocate upon ligand stimulation, the roles of PRAT4A for TLR7 are probably similar to those for TLR9. In this regard, TLR3 seemed to be different from TLR7/9. Although poly(I:C) stimulates both TLR3 and cytoplasmic sensors such as melanoma differentiation-associated gene 5 or retinoic acid–inducible gene I (18), mice lacking TLR3 were shown to be impaired in poly(I:C)-induced production of RANTES and IFN-β by macrophages and in CD86 up-regulation on B cells (19, 20). Given that mice lacking PRAT4A were not impaired in these responses to poly(I:C), PRAT4A is unlikely to be required for TLR3.

Complementation with PRAT4A deletion mutants revealed that the C-terminal 19 aa including the putative ER retention signal (PDEL) was not required for TLRs. We previously reported that TLR4 was still associated with PRAT4A mutants lacking PDEL or the C-terminal 19 aa (Del-1 and -2) (21). As long as PRAT4A is associated with TLRs, the ER retention signal may not be so important. Further study with more deletion mutants is needed to understand the mechanisms by which PRAT4A interacts with TLRs.

Dependency on PRAT4A seems to vary among TLRs and cell types. Although TLR7/9 responses were completely dependent on PRAT4A, TLR2/4 responses were still detectable in PRAT4A^–/– immune cells. PRAT4A-independent TLR2/4 signaling and responses were more evident in BM-DCs than in macrophages or splenic B cells (Figs. 1–3 and 5 A). We previously reported PRAT4B as a molecule similar to PRAT4A in aa sequence and in physical association with TLR4 (21). PRAT4B might be responsible for PRAT4A-independent TLR2/4 responses, particularly in BM-DCs. This possibility is currently being studied.

Despite that cell-surface TLR4 was not detectable on PRAT4A^–/– BM-DCs (Fig. 1 A), there were some responses to lipid A in PRAT4A^–/– mice, and this was most evident in up-regulation of CD86 on BM-DCs (Fig. 5 B), suggesting that intracellular TLR4 may still be able to sense LPS. TLR4 was reported to reside in the Golgi apparatus in intestinal epithelial cells and respond to internalized LPS (22). LPS internalization is dependent on cell-surface CD14 (23). If PRAT4A-independent TLR4 responses are dependent on LPS internalization, PRAT4A-independent lipid A responses should not be detected in CD14-negative cells. Indeed, LPS-induced up-regulation of CD86 was seen in PRAT4A^–/– BM-DCs but not in PRAT4A^–/– B cells (Figs. 3 and Figs.5). LPS-induced up-regulation of CD86 in DCs or macrophages was shown to be dependent on MyD88-independent signaling (24), which induces IRF3 phosphorylation and IFN-β production. Impaired but detectable phosphorylation of IRF3 and IFN-β production was observed with PRAT4A^–/– BM-DCs (Figs. 1 and Figs.5). This was apparently sufficient for up-regulation of a co-stimulatory molecule but not completely sufficient for production of MyD88-independent cytokines such as RANTES and IFN-β. As is the case with TLR9 (25), the subcellular distribution of TLR4/MD-2 might influence LPS responses. Further studies are needed to determine the site of LPS recognition in PRAT4A^–/– cells.

Although TLR1 was not detectable on PRAT4A^–/– BM-DCs, TLR2 was still detectable (Fig. 1 A and not depicted). PCSK was shown to stimulate TLR2 in the absence of TLR1 (26). Interestingly, PCSK-dependent activation of extracellular signal-regulated kinase 1/2 and p38 was delayed in PRAT4A^–/– BM-DCs (Fig. 5 A), suggesting a qualitative difference between PRAT4A-dependent and -independent responses to PCSK. It is possible that only the TLR1-independent signaling pathway was activated in PRAT4A^–/– BM-DCs. PRAT4A^–/– cells might reveal an as yet uncharacterized lipopeptide recognition that is dependent on TLR2 but not TLR1.

Alteration in multiple TLR responses in PRAT4A^–/– cells led to impaired cytokine production against bacteria in vitro and in vivo (Fig. 6, A and C). Of particular interest, IL-12 production in response to heat-killed bacteria was profoundly down-regulated in mice lacking PRAT4A^–/–. In contrast, up-regulation of CD86 in response to heat-killed bacteria was normal in PRAT4A^–/– BM-DCs (Fig. 6 B). Profound defects in multiple TLR responses resulted in a change in adaptive immunity. Upon immunization with OVA mixed with bacteria-containing CFA, PRAT4A^–/– BM chimeric mice failed to mount Th1 responses, as revealed by impaired production of IFN- and OVA-specific IgG2a/c antibody (Fig. 7). Impaired Th1-dependent responses were reported in mice lacking MyD88 (27, 28). PRAT4A^–/– BM-DCs were normal with respect to CD86 up-regulation upon lipid A stimulation and TLR3-dependent responses, both of which are MyD88 independent. Collectively, TLR signaling without PRAT4A may be shifted to MyD88-independent responses, suggesting an unexpected link between the subcellular distribution of TLRs and their downstream signaling pathways. PRAT4A may have a role in determining the balance between MyD88 and MyD88-independent immune responses against a pathogen.

Another change in in vivo immune responses was revealed in the LPS-induced sepsis model. PRAT4A^–/– mice were resistant to the LPS-induced sepsis model (Fig. 8 A). LPS-induced cytokine production in vivo was partially but significantly reduced (Fig. 8 B). It is not clear whether such partial impairment in cytokine production was responsible for resistance against LPS-induced sepsis. Mice treated with lethal doses of LPS succumbed at latencies of up to 4 d (Fig. 8 A), long after serum TNF- and IL-12 returned to basal levels (Fig. 8 B), suggesting that mediators other than these cytokines might contribute to LPS-induced sepsis. In this regard, high-mobility group box 1 (HMGB-1) has been shown to serve as a late mediator in sepsis (29). HMGB-1 has been shown to act on TLRs (30). It is interesting to study whether PRAT4A^–/– cells are impaired in their secretion of or responsiveness to HMGB-1. PRAT4A might have a role in detrimental immune responses in LPS-induced sepsis. In this regard, it is of note that PRAT4A mRNA was down-regulated after responses to a variety of TLR ligands (Fig. S7). PRAT4A mRNA down-regulation might have a role in limiting innate immune responses.

Molecular pathways for responses to highly purified microbial/viral products have been extensively studied, and there is clearly more to learn from that type of experimentation. However, a given immunocyte utilizes combinations of receptors to simultaneously recognize multiple ligands, and there must be mechanisms to ensure that the corresponding response is appropriate. Further studies on PRAT4A would cast light on such mechanisms.

	MATERIALS AND METHODS

Top ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS REFERENCES

 
Generation of PRAT4A^–/– mice and immunizations.
PRAT4A^–/– mice were generated at Unitech. In brief, the targeting vector was constructed to replace the exon 1 with the neomycin resistance gene (Fig. S1). The targeting vector was transfected by electroporation of C57BL/6 embryonic stem (ES) cells. After selection with G418, ES clones were subject to PCR analyses and Southern blotting to identify homologous recombinant clones. Recombinant ES cells were microinjected into C57BL/6 blastocysts to obtain chimeric mice, which were then mated to generate heterozygous and homozygous mice. BM chimeric mice were generated by transferring BM cells from PRAT4A^+/– or PRAT4A^–/– mice into C57BL/6 mice (6–7 wk of age) that had been irradiated at 950 rad. BM chimeric mice were used 6–10 wk after transfer. Chimerism was confirmed by down-regulated TLR2 and RP105 on splenic B cells from PRAT4A^–/– cells.

Chimeric mice were immunized via injections into each hind footpad with OVA emulsified 1:1 in CFA (Difco Laboratories). 8 d after immunization, the draining popliteal and inguinal lymph nodes were isolated, and serum was collected from the mice before (day 0) and after immunization. All animal experiments were conducted with the approval of the Animal Research Committee at the Institute of Medical Science at the University of Tokyo.

Reagents, cells, and mice.
Anti-Flag antibody and anti-Flag–agarose were purchased from Sigma-Aldrich. Anti-HA antibody was purchased from Roche. Anti-GFP antibody was purchased from Invitrogen. The antibodies for flow cytometry (anti-TLR2, anti-CD14, anti-CD11c, and anti-CD86) were purchased from eBioscience. Rat anti–mouse TLR1 mAb (TR23, IgG2a/) was established in our laboratory by immunizing a rat with Ba/F3 cells expressing TLR1. The mAb was chosen that stained the line used for immunization but not the original Ba/F3 cells. pAb to mouse PRAT4A was established in our laboratory by immunizing a rabbit with the fusion protein in which mature mouse PRAT4A (aa 38–276) was fused with glutathione S-transferase.

Lipid A purified from Salmonella minnesota (Re-595) and LPS from E. coli (O55:B5) were purchased from Sigma-Aldrich. PCSK and FSL-1 were purchased from EMC Microcollections. CpG-B (TCCATGACGTTCCTGATGCT) and CpG-A (GGGGTCAACGTTGAGGGGGG) DNA were synthesized by Hokkaido System Science. Poly(I:C) and loxoribine (7-allyl-7,8-dihydro-8-oxo-guanosine) were purchased from InvivoGen.

RAW264, Ba/F3, M12, A20, HEK293, and NIH3T3 cells were cultured as previously described (31). C57BL/6 mice were purchased from Japan SLC Inc. and maintained in the animal facility at the Institute of Medical Science at the University of Tokyo. BM-DCs were prepared as previously described (12). In brief, BM cells were plated at 10⁶ cells per milliliter in 24-well plates with 10% FCS–RPMI 1640 supplemented with 10 ng/ml of recombinant mouse GM-CSF (Genzyme). At day 7, cells were harvested and used for flow cytometry. To enrich PRAT4A^–/– DCs expressing PRAT4A, we used a retroviral vector with the neomycin resistance gene. BM was isolated from PRAT4A^–/– or PRAT4A^+/+ mice that had been injected intraperitoneally 4 d before with 5 mg 5-FU. After 48 h of culture, cells were transduced with retroviral supernatant on two successive days. After the second transduction, cells were washed and cultured in the presence of GM-CSF. During DC induction, 400 µg/ml neomycin was included to enrich DCs expressing shRNA.

Flow cytometry.
Cell-surface staining and analyses on a FACSCalibur (BD Biosciences) were previously described (12).

Immunoprecipitation and immunoprobing.
Immunoprecipitation and immunoprobing were previously described (12). The antibodies used for immunoprobing were anti-Flag (M2), anti-HA, and anti-GFP. The second antibodies were goat anti–mouse IgG–alkaline phosphatase conjugate, goat anti–rat IgG–alkaline phosphatase conjugate (American Qualex), and goat anti–rabbit IgG–alkaline phosphatase conjugate (Bio-Rad Laboratories).

endoH and N-glycosidase assay.
Cells were lysed in 1% Triton X-100 lysis buffer. Lysates were incubated with anti-Flag (M2) or anti-GFP antibody-conjugated beads at 4°C for 2 h. Proteins were eluted and treated with endoH or N-glycosidase according to the manufacturer's instructions (New England Biolabs, Inc.). Samples were subjected to SDS-PAGE and immunoprobing with anti-TLR4 or anti-GFP antibodies.

siRNA.
To inhibit mouse PRAT4A expression, we produced a retroviral vector (provided by H. Iba and T. Mizutani, The University of Tokyo, Tokyo, Japan) expressing shRNA, as previously described (12). The target sequence was 5'-gagtttgaagaggtgattgag-3'. As a control, we used cells expressing an empty vector. For complementation of PRAT4A gene silencing, four silent mutations were introduced in the target sequence, as indicated by underlining (5'-gagttcgaggaagtaattgag-3'). This PRAT4A mutant was cloned into a retroviral vector and transduced into RAW264 cells expressing shPRAT4A.

Quantitative RT-PCR.
Quantitative PCR was conducted as previously described (12). In brief, 1 µg of total RNA was reverse transcribed into complementary DNA using ReverTra Ace -- (TOYOBO), according to the manufacturer's instructions. Quantitative PCR analyses were performed using a PCR system (7300 Fast Real-Time PCR System; Applied Biosystems) with gene expression assays (TaqMan; Applied Biosystems) for mouse PRAT4A (Mm00511161) and IFN-β (Mm00439546). Each sample was normalized using TaqMan gene expression assays for mouse β-actin (Mm00607939).

Immunofluorescence.
Cells were plated on a glass-bottom dish (Matsunami) and used for staining. In some experiments, CpG-rhodamine (Hokkaido System Science) was used to stimulate TLR9-GFP. Cells were fixed by 4% formaldehyde–BS for 10 min at room temperature and washed three times with PBS. To analyze the location of the TLR-GFP fusion proteins, cells were stained with biotinylated cholera toxin subunit B (Sigma-Aldrich), followed by streptavidin–Texas red (Invitrogen), LysoTracker green, or ER tracker red (Invitrogen). DsRed2-ER vector and DsRed-monomer-Golgi vector were purchased from Clontech Laboratories, Inc. TLR-GFP and markers were visualized with confocal microscopy (LSM5 PASCAL; Carl Zeiss, Inc.).

ELISA.
Cells were plated at 10⁵ cells per well in 96-well plates and stimulated with a variety of TLR ligands. After 24 h, supernatant was collected, and concentrations of TNF-, IL-6, IL-12, and RANTES were determined by ELISA kits (R&D Systems). To measure OVA-specific antibodies, 10 µg/ml OVA was used to coat a microtiterplate, and bound Ig isotypes were detected with specific secondary antibodies (horseradish peroxidase–conjugated goat anti–mouse IgM, IgG1, and IgG2c; SouthernBiotech).

Statistical analysis.
Data from triplicate samples were used for statistical analysis. Statistical significance was calculated by the Student's t-test. P < 0.05 was considered significant.

Online supplemental material.
Fig. S1 shows the strategy for the targeted disruption of the mouse PRAT4A gene. Fig. S2 shows that PRAT4A is associated with TLR1 and is required for its cell-surface expression. Fig. S3 shows the physical association between PRAT4A and TLR9. Fig. S4 shows the complementation of PRAT4A knockdown by PRAT4A overexpression in the RAW264.7 macrophage cell line. Fig. S5 shows the complementation of PRAT4A^–/– DCs by retrovirus-mediated overexpression of PRAT4A. Fig. S6 shows the requirement for PRAT4A in cytokine production by BM-DCs against heat-killed M. tuberculosis. Fig. S7 shows down-regulation of PRAT4A mRNA upon stimulation by TLR ligands. Online supplemental material is available at http://www.jem.org/cgi/content/full/jem.20071132/DC1.