HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Schroder, K. Articles by Sweet, M. J. Search for Related Content PubMed PubMed Citation Articles by Schroder, K. Articles by Sweet, M. J. Pubmed/NCBI databases Gene GEO Profiles HomoloGene UniGene Substance via MeSH

Differential Effects of CpG DNA on IFN- Induction and STAT1 Activation in Murine Macrophages versus Dendritic Cells: Alternatively Activated STAT1 Negatively Regulates TLR Signaling in Macrophages¹

Kate Schroder^*, Martina Spille, Andreas Pilz, Jane Lattin^*, Konrad A. Bode, Katharine M. Irvine^*, Allan D. Burrows^*, Timothy Ravasi, Heike Weighardt^¶, Katryn J. Stacey^*,||, Thomas Decker, David A. Hume^*, Alexander H. Dalpke and Matthew J. Sweet^2,*,||

^* Cooperative Research Centre for Chronic Inflammatory Diseases and Special Research Centre for Functional and Applied Genomics, Institute for Molecular Bioscience, University of Queensland, Brisbane, Queensland, Australia; Department of Medical Microbiology and Hygiene, University of Heidelberg, Heidelberg, Germany; Vienna Biocenter, Institute of Microbiology and Genetics, Vienna, Austria; Scripps NeuroAIDS Preclinical Studies Centre and Department of Bioengineering, Jacobs School of Engineering, University of California San Diego, La Jolla, CA 92093; ^¶ Institute for Environmental Research, Heinrich-Heine University, Düsseldorf, Germany; and ^|| School of Molecular and Microbial Sciences, University of Queensland, Brisbane, Queensland, Australia

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
Classical STAT1 activation in response to TLR agonists occurs by phosphorylation of the Y701 and S727 residues through autocrine type I IFN signaling and p38 MAPK signaling, respectively. In this study, we report that the TLR9 agonist CpG DNA induced Ifn- mRNA, as well as downstream type I IFN-dependent genes, in a MyD88-dependent manner in mouse myeloid dendritic cells. This pathway was required for maximal TNF and IL-6 secretion, as well as expression of cell surface costimulatory molecules. By contrast, neither A- nor B-type CpG-containing oligonucleotides induced Ifn- in mouse bone marrow-derived macrophages (BMM) and a CpG-B oligonucleotide did not induce IFn- in the macrophage-like cell line, J774. In BMM, STAT1 was alternatively activated (phosphorylated on S727, but not Y701), and was retained in the cytoplasm in response to CpG DNA. CpG DNA responses were altered in BMM from STAT1_S727A mice; Il-12p40 and Cox-2 mRNAs were more highly induced, whereas Tlr4 and Tlr9 mRNAs were more repressed. The data suggest a novel inhibitory function for cytoplasmic STAT1 in response to TLR agonists that activate p38 MAPK but do not elicit type I IFN production. Indeed, the TLR7 agonist, R837, failed to induce Ifn- mRNA and consequently triggered STAT1 phosphorylation on S727, but not Y701, in human monocyte-derived macrophages. The differential activation of Ifn- and STAT1 by CpG DNA in mouse macrophages vs dendritic cells provides a likely mechanism for their divergent roles in priming the adaptive immune response.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
Activation of innate immune cells such as macrophages and dendritic cells (DC)³ commonly involves concerted signaling by cytokines such as IFNs, and microbial products such as LPS and CpG DNA (1). Many cytokines act through members of the hemopoietin receptor family, and their actions are coupled to the JAK-STAT signaling cascade. Microbial products act through the TLR family, which are coupled via adaptor proteins such as MyD88 to downstream effectors such as NF-B. IFNs prime for maximal activation in response to the TLR agonists LPS and CpG DNA, and the IFN-responsive STAT family member STAT1 can integrate the two pathways; IFNs and LPS both induce STAT1 phosphorylation and STAT1-dependent gene expression (1, 2).

TLRs differ in the use of specific adaptors and consequent induction of target genes. The response to LPS requires TLR4 (3), which signals through both MyD88-independent (mediated by the TIR domain-containing adaptor proteins 1 and 2 and MyD88-dependent pathways (reviewed in Ref. 4). By contrast, CpG DNA-dependent signaling via TLR9 absolutely requires MyD88 (5). Consequently, LPS, but not CpG DNA, induces a set of MyD88-independent genes in macrophages (6, 7). One of the MyD88-independent genes induced by LPS in macrophages encodes the type I IFN, IFN- (8, 9). LPS-induced IFN- acts in an autocrine fashion to activate tyrosine phosphorylation of STAT1, which in turn induces a set of target genes, including inducible NO synthetase in macrophages (9, 10).

TLR signaling also modifies STAT1 more directly through phosphorylation at S727 (11, 12), which occurs via a p38 MAPK-dependent pathway (13, 14, 15). The contributions of S727 phosphorylation to the actions of STAT1 were analyzed using STAT1_S727A mutant mice, in which an alanine is substituted for the serine at residue 727 of STAT1 (12). These mice were resistant to LPS shock, and macrophages from these mice were less sensitive to the combined effects of IFN- plus LPS in vitro (12). Phosphorylation of STAT1 on Y701 is required for homo- and heterodimerization and for nuclear translocation and transcriptional activation. Nevertheless, STAT1 phosphorylated at S727, but not Y701, can still regulate gene expression (16, 17, 18, 19, 20). STAT1 serine phosphorylation was required, whereas tyrosine phosphorylation and homodimerization were dispensable, for maximal constitutive expression of caspase-2 and -3 in fibroblasts (16). Furthermore, Y701 mutants of STAT1 still regulated the constitutive expression of several genes, including CycA, Hsp70, and Lmp2, in fibroblasts (17).

Early studies on CpG DNA signaling in macrophages implied that this stimulus did not elicit type I IFN production (21, 22), consistent with the inability of CpG DNA to activate MyD88-independent signaling pathways (5). However, recent reports demonstrated that CpG DNA triggered IFN- production in myeloid DC in a MyD88-dependent fashion via IFN regulatory factor (IRF)1 (23, 24). In addition, in plasmacytoid DC (pDC), endosomal retention of CpG DNA enabled MyD88-dependent activation of the IRF family member, IRF7, leading to type I IFN production (25, 26). CpG-containing oligonucleotides that effectively induce type I IFN in pDC are termed A type and have a palindromic central CpG motif, which can form a double-stranded region, and strings of G residues at both the 3' and 5' ends. A-type and conventional single-stranded B-type CpG-containing oligonucleotides traffic differentially in pDC; A-type oligonucleotides are retained in early endosome-like structures and initiate signaling leading to type I IFN production, whereas B-type oligonucleotides traffic to a late endosome/lysosome compartment and more strongly induce inflammatory cytokines, such as TNF (26). Differences between macrophages and DC in their response to MyD88-dependent signals could be important in constraining pathological consequences of macrophage activation (e.g., septic shock), while permitting activation of acquired immunity.

In this study, we confirm that macrophages differ from DC in their response to MyD88-dependent signaling by CpG DNA. The MyD88-dependent production of IFN- was essential for CpG DNA-mediated DC maturation, and provides an important insight into the powerful adjuvant activity of CpG DNA. Conversely, the failure of macrophages to respond to CpG DNA with inducible IFN- expression reveals a novel cytoplasmic function for STAT1, which limits the production of a subset of inflammatory mediators. We propose that the divergent responses of macrophages and DC to CpG DNA could derive from differential expression of members of the IRF family.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
General reagents

Recombinant mouse IFN- (R&D Systems) and IFN- (PBL) were used at a final concentration of 500 pg/ml and 100 U/ml, respectively. LPS (from Salmonella minnesota; Sigma-Aldrich) was used at a final concentration of 10 ng/ml, unless otherwise stated. Lipoteichoic acid (LTA) from Staphylococcus aureus was a gift from S. Morath (Konstanz, Germany); PAM₃CSK₄ was obtained from EMC Microcollections. R837 (imiquimod), a specific TLR7 agonist (27, 28), was purchased from InvivoGen. Human rCSF-1 (a gift from Chiron) was used at a final concentration of 1 x 10⁴ U/ml (100 ng/ml). Unless otherwise stated, the well-characterized B-type phosphorothioate-modified oligonucleotide 1668S (5'-tccatgacgttcctgatgct-3') (29) was used in all experiments at a final concentration of 0.1 µM. The GC inversion of this oligonucleotide, 1668S-GC, 5'-tccatgagcttcctgatgct-3', was used to control for CpG DNA-independent effects on cells (29). In experiments in which A-type oligos were examined, the D19 oligonucleotide (5'-ggTGCATCGATGCAgggggG-3') (26) and the 1585 oligonucleotide (5'-ggGGTCAACGTTGAgggggG-3') (30) were used. Upper and lower case letters indicate bases with phosphodiester- and phosphorothioate-modified linkages, respectively. All oligonucleotides were synthesized by Geneworks. Abs used in Western blotting were purchased from Cell Signaling Technology (anti-STAT1, anti-phospho-Y701-STAT1, anti-p38 MAPK, anti-phospho-p38 MAPK, anti-ERK-1/2, anti-phospho-ERK-1/2, anti-CSF-1R, goat anti-rabbit IgG), Calbiochem (anti-phospho-S727-STAT1), or Santa Cruz Biotechnology (anti-PU.1). All primary Abs were used at 1:1000, except anti-PU.1, which was used at 1:5000, whereas the secondary Ab was used at 1:3000.

Preparation of macrophages and DC

Bone marrow-derived macrophages (BMM) were obtained by ex vivo differentiation from mouse bone marrow progenitors in the presence of rCSF-1 over 7 days, as described previously (31, 32). C57BL/6 male mice (6–8 wk old) kept under specific pathogen-free conditions were used in BMM generation. For experiments with wild-type (WT) vs STAT1_S727A mice, bone marrow progenitors were pooled from equal numbers of age-matched male and female mice in each experiment. J774 macrophages (American Type Culture Collection) were maintained in RPMI 1640 supplemented with 5% FCS and antibiotics (100 IU/ml penicillin G and 100 IU/ml streptomycin sulfate). GM-CSF-derived (CD11c⁺, B220^–) bone marrow-derived DC (BMDC) were prepared, as described previously (33), from C57BL/6 female 6- to 8-wk-old mice. Where the effect of IFNAR1 or MyD88 genotype was examined, SV129 IFNAR1^+/+, SV129 IFNAR1^–/–, BALB/c MyD88^+/+, or BALB/c MyD88^–/– mice were used as a source of DC and BMM. All experiments with mouse primary cells were conducted in accordance with local animal ethics guidelines.

Human macrophages were derived from monocytes isolated from blood donations obtained from the Australian Red Cross Blood Bank. PBMC were separated from buffy coat by Ficoll-Paque (Amersham) density centrifugation. CD14⁺ monocytes were isolated from the PBMC by positive selection for CD14 using MACS magnetic beads (Miltenyi Biotec), according to the manufacturer’s instructions. Monocytes were seeded on tissue culture plastic at 15 x 10⁶ per plate in IMDM (Invitrogen Life Technologies) with 10% FCS, CSF-1, and antibiotics, as above, and allowed to differentiate into macrophages for 6 days. Macrophages were supplemented with CSF-1-replete medium on day 5, and both the adherent and nonadherent cells were reseeded on day 6 and harvested for analysis on day 7.

Determination of mRNA expression by quantitative PCR (qPCR)

Cellular RNA was extracted using RNeasy kits (Qiagen) or HighPure RNA kits (Roche). Contaminating genomic DNA was removed using DNA-Free (Ambion), and cDNA was synthesized using Superscript III (Invitrogen Life Technologies) or reverse transcriptase (MBI Fermentas) and oligo(dT) primer. Negative control reactions were performed as above, with the omission of the enzyme. cDNA was quantitated using the Platinum SYBR Green quantitative PCR system (Invitrogen Life Technologies) or TaqMan reagents (AbGene) and fluorogenic probes (FAM/TAMRA; Eurogentec). Negative control reactions were cycled alongside test samples to ensure the absence of contaminating genomic DNA. Data were analyzed using ABI Prism software. Expression was determined relative to the abundance of housekeeping genes (SYBR Green, hypoxanthine guanine phosphoribosyltransferase Hprt; TaqMan, -actin). Transcript abundance (Gene/Hprt or Gene/-actin) and SD were determined, as recommended by Applied Biosystems. Where inducible expression in cells of different genotypes was compared, expression was determined as a fold induction relative to basal expression within the genotype. Profiles were quantitated in at least three separate experiments using completely independent preparations of cells and RNA extracts, unless otherwise stated. Real-time PCR primer pairs were designed and tested as described previously (34). Primer sequences are available on request.

ELISA

The levels of secreted cytokines (IFN--inducible protein-10 (IP-10), TNF, and IL-6) in culture supernatants were determined using ELISA kits (OptEiA; BD Biosciences).

Flow cytometry

Cell surface proteins were stained using anti-CD80 and anti-CD86 Abs (BD Biosciences) and analyzed by flow cytometry using a FACS Canto (BD Biosciences).

Immunoblot analysis

Western analysis of phospho-specific protein forms included phosphatase inhibitors (1 mM sodium vanadate, 1 mM sodium pyrophosphate, 1 mM sodium molybdate, 10 mM sodium fluoride) in all steps of protein extract preparation and immunodetection. The fractionation of nuclear and extranuclear proteins was performed at 4°C, and all solutions for extract preparation were prechilled and included 5 µM PMSF and 1x protease inhibitors (Roche). Cells were harvested and washed twice with PBS. The cell pellet was resuspended in 225 µl of plasma membrane lysis buffer (10 mM HEPES (pH 7.4), 1.5 mM MgCl₂, 10 mM KCl, 0.1% Nonidet P-40) per 10 x 10⁶ cells, and incubated for 5 min. Nuclei were separated from the solubilized extranuclear extract by centrifugation, and the nuclei were washed three times with plasma membrane lysis buffer. Nuclei were resuspended in 75 µl of nuclei lysis buffer (20 mM HEPES (pH 7.8), 420 mM NaCl, 20% glycerol, 0.2 mM EDTA, 1.5 mM MgCl₂) per 10 x 10⁶ cells and incubated for 10 min. The nuclear extract was clarified by centrifugation. Total protein in whole cell, nuclear, and extranuclear extracts was quantitated using the BCA Protein Assay Kit (Pierce) to normalize total protein loading. Whole cell extracts were prepared by boiling lysis (35), and whole cell and fractionated extracts were analyzed by Western blot, as described previously (35, 36).

	Results

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
CpG DNA induces type I IFN and downstream target genes via MyD88 in mouse DC, but not macrophages

CpG DNA did not induce IFN- expression in mouse bone marrow-derived macrophages (BMM) or RAW264.7 cells (26), but recent studies have identified a MyD88-dependent pathway leading to Ifn- production in BMDC (8, 23, 24). Fig. 1 shows a direct comparison of the effects of the B-type CpG DNA, 1668S, on mouse macrophages and DC. CpG DNA strongly induced Ifn- mRNA expression (Fig. 1A), as well as expression of the type I IFN target gene, Ip-10 (Fig. 1B) in BMDC. In contrast, the mouse macrophage cell line J774 responded to LPS, but not CpG DNA, with inducible Ifn- mRNA expression (Fig. 1C), as well as downstream responses such as induction of Ip-10 mRNA (Fig. 1D) and protein (data not shown). The responsiveness of J774 cells to both stimuli was confirmed by assessing Tnf mRNA expression (data not shown). Similarly, stimulation of BMM with LPS, but not CpG DNA, for 3 h elicited robust Ifn- mRNA expression (Fig. 1E). In these cells, the TLR2 ligands, Pam₃CSK₄ and LTA, were also ineffective at inducing Ifn- gene expression (Fig. 1E). Even after prolonged incubation with CpG DNA, there was no induction of Ifn- (Fig. 1F), whereas Il-12p40 (Fig. 1G) and Tnf (data not shown) were highly induced.

View larger version (31K): [in this window] [in a new window]   FIGURE 1. CpG DNA induces Ifn- and IFN--dependent gene expression in BMDC, but not macrophages. BMDC (A and B), J774 cells (C and D), and BMM (E) were stimulated with varying doses of CpG DNA or LPS for 3 h. Experiments with BMM also included stimulation with 5 µg/ml PAM3CSK4 (P3C) or 10 µg/ml LTA. Total cellular RNA was prepared, and the mRNA expression of Ifn- (A, C, and E) and Ip-10 (B and D), relative to -actin (A–E) was determined by qPCR. Data points represent the average of duplicates + SD. Profiles are representative of two independent experiments. F and G, BMM were stimulated with CpG DNA (0.1 µM) or LPS (10 ng/ml) over a time course (F and G). Total cellular RNA was prepared, and mRNA expression of Ifn- (F) and Il-12p40 (G) relative to Hprt was determined by qPCR. H–J, BMM were stimulated with 0.1 µM or 1 µM A-type CpG DNA (D19, 1585), B-type CpG DNA (1668S, 0.1 µM), or LPS (10 ng/ml) for 2 h. Total cellular RNA was prepared, and mRNA expression of Ifn- (H), Ip-10 (I), and Tnf (J) relative to Hprt was determined by qPCR. Data points represent the average of triplicates + SD. Profiles are representative of at least three independent experiments.

The response to CpG DNA and other TLR agonists is dependent upon the adaptor protein MyD88. Although LPS elicited IP-10 production in both BMM (Fig. 2A) and BMDC (Fig. 2C) from MyD88-deficient mice, production of IP-10 in response to CpG DNA was absolutely dependent on MyD88 in BMDC. As expected, TNF production from both BMM (Fig. 2B) and BMDC (Fig. 2D) was either partially dependent (LPS) or totally dependent (CpG DNA) on MyD88. Hence, CpG DNA-triggered IFN- production in the myeloid DC lineage is MyD88 dependent. By extension, because macrophages can respond to CpG DNA (and TLR2 agonists) in a MyD88-dependent manner, the signaling blockade in these cells lies specifically within the pathways linking MyD88 to IFN- production.

View larger version (24K): [in this window] [in a new window]   FIGURE 2. CpG DNA-induced IFN--dependent gene expression in BMDC is dependent on MyD88. BMM (A and B) and BMDC (C and D) derived from WT () or MyD88 knockout mice () were stimulated with varying doses of CpG DNA or LPS overnight. Culture supernatants were assayed for secretion of IP-10 (A and C) and TNF (B and D) by ELISA. Data points represent the average of triplicates + SD. Profiles are representative of two independent experiments.

Autocrine actions of CpG DNA-induced IFN- have not been widely implicated in DC maturation. We assessed the phenotype of BMDC derived from mice in which the IFN- receptor is nonfunctional due to targeted deletion of the receptor subunit IFNAR1. As expected, induction of Ip-10 mRNA by LPS and CpG DNA was impaired in BMDC from IFNAR1-deficient animals (Fig. 3A). CpG DNA- and LPS-mediated up-regulation of surface expression of the costimulatory molecules CD80 (Fig. 3B) and CD86 (Fig. 3C), as well as production of both TNF (Fig. 3D) and IL-6 (Fig. 3E), was also dependent on type I IFN signaling. However, this pathway did not play a major role in the response to Pam3Cys (Fig. 3, D and E).

View larger version (26K): [in this window] [in a new window]   FIGURE 3. CpG DNA-induced cytokine production and induction of costimulatory molecules are dependent on type I IFN in BMDC. BMDC derived from WT () or IFNAR1 knockout mice () were stimulated with 1 µM CpG DNA or 100 ng/ml LPS in matched samples over a 24-h time course. Total cellular RNA was prepared, and mRNA expression of Ip-10 (A) relative to -actin was determined by qPCR. Data points represent the average of duplicates + SD. Profiles are representative of at least two independent experiments. WT or IFNAR1 BMDC were stimulated with 1 µM CpG DNA or 100 ng/ml LPS for 20 h. Surface expression of CD80 (B) and CD86 (C) was analyzed by FACS. Data points represent the average of three quantitations using cells derived from separate mice + SD. Profiles are representative of three independent experiments. WT or IFNAR1 knockout BMDC (D and E), J774 macrophages (F and G), or BMDC (H and I) were stimulated with varying doses of CpG DNA or LPS overnight, in the presence or absence of 100 U/ml IFN- (F–I). Culture supernatants were harvested and assayed for TNF (D, F, and H) and IL-6 (E, G, and I) secretion by ELISA. Data points represent the average of duplicate quantitations + SD. Profiles are representative of three independent experiments.

CpG DNA activates serine, but not tyrosine, phosphorylation of STAT1 in BMM

TLR agonists activate STAT1 phosphorylation on S727 via a p38-dependent pathway (13). Since IFN- was not produced in response to CpG DNA in macrophages (Fig. 1), CpG DNA induced an alternative STAT1 activation state in which S727, but not Y701, was phosphorylated in BMM (Fig. 4A). In contrast, both LPS (Fig. 4B) and IFN- (Fig. 4C) triggered dual Y701/S727 phosphorylation of STAT1 in BMM, as previously reported (38, 39, 40). The time course of Y701 phosphorylation in response to LPS was delayed, reflecting the autocrine nature of IFN- signaling.

View larger version (60K): [in this window] [in a new window]   FIGURE 4. CpG DNA triggers S727, but not Y701, STAT1 phosphorylation in BMM. BMM were treated with A, CpG DNA or the GC inversion of the CpG DNA oligonucleotide (GC, for 1 h) to control for CpG DNA-independent effects; B, LPS; or C, IFN- over a time course. Phospho-S727 STAT1 (p-S727), phospho-Y701 STAT1 (p-Y701), and total STAT1 in whole cell extracts were detected by immunoblotting. A positive control (con, 0.5-h IFN- stimulation) was included for the detection of phospho-Y701 STAT1 on blots containing CpG DNA time courses. Profiles are indicative of at least three independent experiments.

View larger version (58K): [in this window] [in a new window]   FIGURE 5. S727-phosphorylated STAT1 is retained in the cytoplasm following CpG DNA stimulation. BMM were treated with CpG DNA, LPS, or IFN-, and the cellular localization of STAT1 was monitored. The nuclear and extranuclear compartments were fractionated, and levels of phospho-S727 STAT1 (p-S727), phospho-Y701 STAT1 (p-Y701), total STAT1, PU.1, and CSF-1R in the nuclear and extranuclear cell extracts were detected by immunoblotting. Phospho-STAT1, total STAT1, and PU.1 profiles are representative of at least two independent experiments.

The function of STAT1 S727 phosphorylation in the CpG DNA response was examined using mice in which the S727 residue was replaced with an alanine (STAT1_S727A mice) (12). BMM from these mice showed a selective defect in serine phosphorylation in response to CpG DNA or IFN-, whereas IFN--dependent Y701 phosphorylation was intact (Fig. 6A). STAT1-independent signaling by CpG DNA was unaffected by the S727 mutation, because ERK-1/2 activation in response to CpG DNA was comparable between WT and STAT1_S727A BMM (Fig. 6B).

View larger version (43K): [in this window] [in a new window]   FIGURE 6. CpG DNA-induced ERK phosphorylation is intact in STAT1S727A BMM. A, BMM from WT and STAT1S727A mice were stimulated with CpG DNA over a 2-h time course in matched samples. Levels of phospho-S727 STAT1 (p-S727), phospho-Y701 STAT1 (p-Y701), and total STAT1 in whole cell extracts were detected by immunoblotting. A positive control for Y701 STAT1 phosphorylation (C, 0.5-h IFN- stimulation) was included in the time course. B, BMM from WT and STAT1S727A mice were stimulated with CpG DNA over a 7-h time course in matched samples. Cells were also treated with the GpC DNA-negative control oligonucleotide (C, 0.25-h GpC DNA). Levels of phospho-ERK-1/2 (p-ERK) and total ERK-1/2 were determined by immunoblotting.

View larger version (27K): [in this window] [in a new window]   FIGURE 7. CpG DNA-modulated gene expression is selectively dysregulated in STAT1S727A BMM. BMM from WT () and STAT1S727A mice () were stimulated with CpG DNA over a 21-h time course. Total cellular RNA from matched samples was extracted, and mRNAs for Il-12p40 (A), Cox-2 (B), Il-6 (C), Tnf (D), Tlr4 (E), and Tlr9 (F) were measured by quantitative PCR. Expression is shown as fold induction over basal expression within the genotype. Profiles are representative of three independent experiments.

It is generally accepted that human monocytes do not respond to CpG DNA, which might imply that STAT1 cannot be alternatively activated in human monocytes or macrophages. We hypothesized, however, that any TLR agonist that activates the p38 MAPK pathway without concomitant induction of autocrine IFN- signaling would initiate alternative STAT1 activation in human macrophages. We therefore examined the activation of this pathway in response to the TLR7 agonist, R837 (imiquimod) (27, 28), in HMDM. Although LPS strongly induced Ifn- mRNA as expected, R837 was ineffective at inducing Ifn- mRNA (Fig. 8A) or the IFN- target gene Ip-10 (Fig. 8B) in HMDM. In contrast, this signal triggered robust Il-1 mRNA expression (330-fold, Fig. 8C) and p38 MAPK phosphorylation (Fig. 8D). Consistent with the ability of R837 to activate p38 MAPK, but not IFN- signaling (Fig. 8, A, B, and D), R837 elicited alternative STAT1 activation (monophosphorylation at S727), whereas LPS triggered classical STAT1 activation (S727 and Y701 phosphorylation) in HMDM (Fig. 8D). Thus, alternative and classical STAT1 activation occur in both mouse and human primary macrophages.

View larger version (23K): [in this window] [in a new window]   FIGURE 8. R837 triggers S727, but not Y701, STAT1 phosphorylation in HMDM. HMDM were treated with 10 µg/ml R837 or 10 ng/ml LPS for 2 h. A–C, Total cellular RNA was prepared, and mRNA expression of Ifn- (A), Ip-10 (B), and Il-1 (C) relative to Hprt was determined by qPCR. Data points represent the average of triplicates + SD. D, Phospho-S727 STAT1 (p-S727), phospho-Y701 STAT1 (p-Y701), total STAT1, phospho-p38 MAPK (p-p38), and total p38 MAPK in whole cell extracts were detected by immunoblotting. RNA and protein profiles are indicative of duplicate experiments from independent blood donors.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

In macrophages, even A-type oligonucleotides were ineffective at inducing Ifn- mRNA expression (Fig. 1H) and downstream IFN target genes (Fig. 1I). The endosomal trafficking of A-type oligonucleotides leading to IRF7-dependent induction of type I IFN (26) is likely to be unique to the antiviral function of pDC. The use of the autocrine type I IFN pathway in DC, but not macrophages, may contribute to the enhanced capacity of DC to act as professional APC, and implies that endogenous IFN contributes to functional divergence between macrophages and myeloid DC. The differential responses of DC and macrophages to CpG DNA are summarized in Fig. 9.

View larger version (50K): [in this window] [in a new window]   FIGURE 9. Model for divergent STAT1 activation and function in response to CpG DNA in DC vs macrophages. CpG DNA stimulation of DC causes STAT1 phosphorylation at both the S727 and Y701 residues. S727 phosphorylation occurs rapidly (within 30 min) and is mediated by a p38 MAPK-dependent pathway. Y701 phosphorylation occurs in a delayed fashion (2 h), and is mediated by the autocrine activity of CpG DNA-induced IFN-. Y701/S727-double phosphorylated STAT1 dimerizes and translocates to the nucleus to trans activate classic STAT1 target genes such as Ip-10 and to induce costimulatory molecule expression and proinflammatory cytokine production. CpG DNA stimulation of macrophages triggers phosphorylation of STAT1 at the S727 residue only. In contrast to DC, CpG DNA does not induce the production and autocrine activities of IFN- in macrophages, and so STAT1 remains in the Y701-unphosphorylated form that cannot dimerize or translocate to the nucleus. Cytoplasmic STAT1 indirectly modulates gene expression (e.g., Tlr4, Tlr9, Cox-2, Il-12p40), perhaps by cytoplasmic sequestration of gene regulatory factors.

Although CpG DNA did not activate the classical type I IFN-dependent pathway in BMM, the phosphorylation of STAT1 on S727 (Fig. 4) led to an alternative activation state in which STAT1 was retained in the cytoplasm (Fig. 5). Gene expression profiles comparing WT and S727A STAT1 mutant macrophages (Fig. 7) suggest that phosphorylation on this amino acid contributes to CpG DNA-mediated signaling in macrophages. Serine phosphorylation of STAT1 regulates interactions with several binding partners (e.g., BRCA1, CBP, MCM5 (12, 46, 47, 48)). On this basis, we propose that S727-phosphorylated STAT1 functions to sequester transcriptional regulators in the cytoplasm of CpG DNA-stimulated macrophages. Such a mechanism was demonstrated in osteoblasts, where serine-phosphorylated STAT1 sequestered the RUNX2 transcription factor in the cytoplasm in an inducible manner that was independent of Y701 phosphorylation (49).

One possibility is that members of the IRF family could be targeted for cytoplasmic sequestration by S727-phosphorylated STAT1 in macrophages. For example, IRF9, which normally resides in both the nucleus and cytoplasm, was retained in the cytoplasm when coexpressed with STAT2 (50). The IRF9 nuclear localization signal is contained within the DNA binding domain and is conserved in IRF8 and IRF4 (50), and it is possible that these IRFs could be inducibly retained by STAT1 in the cytoplasm of macrophages, upon S727 phosphorylation. In support of such a mechanism, IRF8 was reported to bind to nontyrosine-phosphorylated STAT1 (51). Other IRF family members are also candidates. IRF1, which was reported to interact with STAT1 (17), positively regulated the inducible expression of Cox-2 (52) and Il-12-p40 (53), both of which were superinduced by CpG DNA in STAT1_S727A BMM (Fig. 7). Similarly, IRF2, which can also form a complex with STAT1 (54), was implicated in driving IL-12p40 expression (53). STAT1_S727A BMM may therefore permit the nuclear translocation of one or more IRF family members and the superinduction of Cox-2, Il-12-p40, and coregulated genes in response to CpG DNA; we are currently investigating this hypothesis.

The differing activity profiles of STAT1 in response to CpG DNA and LPS may underpin their very different toxicities. IFN- signaling and classic STAT1 trans-activator function in macrophages contributes to LPS-mediated toxicity in vivo (55, 56). CpG DNA is less toxic than LPS in vivo, and the apparently anti-inflammatory actions of alternatively activated STAT1 may be protective in this context.

Alternative STAT1 activation was not just restricted to CpG DNA signaling in mouse macrophages. The TLR7 agonist, R837, induced a similar activation profile (monophosphorylation at S727) due to a failure of autocrine IFN- signaling in HMDM (Fig. 8). It is likely that a range of stimuli that activate the p38 MAPK pathway without inducing autocrine IFN signaling trigger alternative STAT1 activation. Furthermore, this pathway may also operate as a feedback regulator of TLR4 signaling because LPS triggers sustained S727 phosphorylation, but transient Y701 phosphorylation (Fig. 4). That is, a shift from classical to alternative STAT1 function after prolonged activation via TLR4 may act to sequester transcriptional activators in the cytoplasm.

In summary, we propose that the IFN-/STAT1 axis is a key regulator of CpG DNA signaling, and that divergent activation of this pathway between macrophages and DC dictates cell-specific responses to CpG DNA. CpG DNA induces autocrine IFN- signaling and classic STAT1 transcription factor activities in myeloid DC, thereby potentiating expression of IFN-target genes, costimulatory molecules (CD80 and CD86), and proinflammatory cytokines (IL-6, TNF). The lack of this autocrine pathway in CpG DNA-stimulated macrophages enables alternative STAT1 activities that may include sequestration of gene regulatory factors to limit CpG DNA responses. This blockade could be overcome by IFN-, which can induce STAT1 Y701 phosphorylation and nuclear translocation. In such a scenario, STAT1 would be rapidly transformed from signaling repressor to transcriptional activator to elicit appropriate antimicrobial responses.

	Disclosures

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
The authors have no financial conflict of interest.

	Footnotes

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ This work was supported by grants from the National Health and Medical Research Council of Australia (Project Grants 301211 and 301210). T.R. was supported by a research grant for the Scripps NeuroAIDS Preclinical Studies Center from the National Institute of Mental Health, Grant 2P30MH062261-07. A.H.D. was supported by Grants DFG Da592/2 and 592/3 from the German research foundation.

² Address correspondence and reprint requests to Dr. Matthew J. Sweet, Institute for Molecular Bioscience, University of Queensland, St. Lucia, Queensland, 4072, Australia. E-mail address: M.Sweet{at}imb.uq.edu.au

³ Abbreviations used in this paper: DC, dendritic cell; BMDC, bone marrow-derived DC; BMM, bone marrow-derived macrophage; HMDM, human monocyte-derived macrophage; IP-10, IFN--inducible protein-10; IRF, IFN regulatory factor; LTA, lipoteichoic acid; pDC, plasmacytoid DC; qPCR, quantitative PCR; WT, wild type.

Received for publication April 5, 2007. Accepted for publication July 3, 2007.

	References

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 

1. Schroder, K., P. J. Hertzog, T. Ravasi, D. A. Hume. 2004. Interferon-: an overview of signals, mechanisms and functions. J. Leukocyte Biol. 75: 163-189. [Abstract/Free Full Text]
2. Schroder, K., M. J. Sweet, D. A. Hume. 2006. Signal integration between IFN and TLR signalling pathways in macrophages. Immunobiology 211: 511-524. [Medline]
3. Hoshino, K., O. Takeuchi, T. Kawai, H. Sanjo, T. Ogawa, Y. Takeda, K. Takeda, S. Akira. 1999. Cutting edge: Toll-like receptor 4 (TLR4)-deficient mice are hyporesponsive to lipopolysaccharide: evidence for TLR4 as the Lps gene product. J. Immunol. 162: 3749-3752. [Abstract/Free Full Text]
4. Vogel, S. N., K. A. Fitzgerald, M. J. Fenton. 2003. TLRs: differential adapter utilization by Toll-like receptors mediates TLR-specific patterns of gene expression. Mol. Intervent. 3: 466-477. [Abstract/Free Full Text]
5. Schnare, M., A. C. Holt, K. Takeda, S. Akira, R. Medzhitov. 2000. Recognition of CpG DNA is mediated by signaling pathways dependent on the adaptor protein MyD88. Curr. Biol. 10: 1139-1142. [Medline]
6. Gao, J. J., V. Diesl, T. Wittmann, D. C. Morrison, J. L. Ryan, S. N. Vogel, M. T. Follettie. 2003. Bacterial LPS and CpG DNA differentially induce gene expression profiles in mouse macrophages. J. Endotoxin Res. 9: 237-243. [Medline]
7. Gao, J. J., V. Diesl, T. Wittmann, D. C. Morrison, J. L. Ryan, S. N. Vogel, M. T. Follettie. 2002. Regulation of gene expression in mouse macrophages stimulated with bacterial CpG-DNA and lipopolysaccharide. J. Leukocyte Biol. 72: 1234-1245. [Abstract/Free Full Text]
8. Hoshino, K., T. Kaisho, T. Iwabe, O. Takeuchi, S. Akira. 2002. Differential involvement of IFN- in Toll-like receptor-stimulated dendritic cell activation. Int. Immunol. 14: 1225-1231. [Abstract/Free Full Text]
9. Toshchakov, V., B. W. Jones, P. Y. Perera, K. Thomas, M. J. Cody, S. Zhang, B. R. Williams, J. Major, T. A. Hamilton, M. J. Fenton, S. N. Vogel. 2002. TLR4, but not TLR2, mediates IFN--induced STAT1/-dependent gene expression in macrophages. Nat. Immunol. 3: 392-398. [Medline]
10. Ohmori, Y., T. A. Hamilton. 2001. Requirement for STAT1 in LPS-induced gene expression in macrophages. J. Leukocyte Biol. 69: 598-604. [Abstract/Free Full Text]
11. Wen, Z., Z. Zhong, J. E. Darnell, Jr. 1995. Maximal activation of transcription by Stat1 and Stat3 requires both tyrosine and serine phosphorylation. Cell 82: 241-250. [Medline]
12. Varinou, L., K. Ramsauer, M. Karaghiosoff, T. Kolbe, K. Pfeffer, M. Muller, T. Decker. 2003. Phosphorylation of the Stat1 transactivation domain is required for full-fledged IFN--dependent innate immunity. Immunity 19: 793-802. [Medline]
13. Kovarik, P., D. Stoiber, P. A. Eyers, R. Menghini, A. Neininger, M. Gaestel, P. Cohen, T. Decker. 1999. Stress-induced phosphorylation of STAT1 at Ser727 requires p38 mitogen-activated protein kinase whereas IFN- uses a different signaling pathway. Proc. Natl. Acad. Sci. USA 96: 13956-13961. [Abstract/Free Full Text]
14. Uddin, S., F. Lekmine, N. Sharma, B. Majchrzak, I. Mayer, P. R. Young, G. M. Bokoch, E. N. Fish, L. C. Platanias. 2000. The Rac1/p38 mitogen-activated protein kinase pathway is required for interferon -dependent transcriptional activation but not serine phosphorylation of Stat proteins. J. Biol. Chem. 275: 27634-27640. [Abstract/Free Full Text]
15. Ramsauer, K., I. Sadzak, A. Porras, A. Pilz, A. R. Nebreda, T. Decker, P. Kovarik. 2002. p38 MAPK enhances STAT1-dependent transcription independently of Ser-727 phosphorylation. Proc. Natl. Acad. Sci. USA 99: 12859-12864. [Abstract/Free Full Text]
16. Kumar, A., M. Commane, T. W. Flickinger, C. M. Horvath, G. R. Stark. 1997. Defective TNF--induced apoptosis in STAT1-null cells due to low constitutive levels of caspases. Science 278: 1630-1632. [Abstract/Free Full Text]
17. Chatterjee-Kishore, M., K. L. Wright, J. P. Ting, G. R. Stark. 2000. How Stat1 mediates constitutive gene expression: a complex of unphosphorylated Stat1 and IRF1 supports transcription of the LMP2 gene. EMBO J. 19: 4111-4122. [Medline]
18. Agrawal, S., M. L. Agarwal, M. Chatterjee-Kishore, G. R. Stark, G. M. Chisolm. 2002. Stat1-dependent, p53-independent expression of p21^waf1 modulates oxysterol-induced apoptosis. Mol. Cell. Biol. 22: 1981-1992. [Abstract/Free Full Text]
19. Stephanou, A., T. M. Scarabelli, B. K. Brar, Y. Nakanishi, M. Matsumura, R. A. Knight, D. S. Latchman. 2001. Induction of apoptosis and Fas receptor/Fas ligand expression by ischemia/reperfusion in cardiac myocytes requires serine 727 of the STAT-1 transcription factor but not tyrosine 701. J. Biol. Chem. 276: 28340-28347. [Abstract/Free Full Text]
20. Kim, H. S., M. S. Lee. 2005. Essential role of STAT1 in caspase-independent cell death of activated macrophages through the p38 mitogen-activated protein kinase/STAT1/reactive oxygen species pathway. Mol. Cell. Biol. 25: 6821-6833. [Abstract/Free Full Text]
21. Sweet, M. J., K. J. Stacey, D. K. Kakuda, D. Markovich, D. A. Hume. 1998. IFN- primes macrophage responses to bacterial DNA. J. Interferon Cytokine Res. 18: 263-271. [Medline]
22. Stacey, K. J., M. J. Sweet, D. A. Hume. 1996. Macrophages ingest and are activated by bacterial DNA. J. Immunol. 157: 2116-2122. [Abstract]
23. Schmitz, F., A. Heit, S. Guggemoos, A. Krug, J. Mages, M. Schiemann, H. Adler, I. Drexler, T. Haas, R. Lang, H. Wagner. 2007. Interferon-regulatory-factor 1 controls Toll-like receptor 9-mediated IFN- production in myeloid dendritic cells. Eur. J. Immunol. 37: 315-327. [Medline]
24. Negishi, H., Y. Fujita, H. Yanai, S. Sakaguchi, X. Ouyang, M. Shinohara, H. Takayanagi, Y. Ohba, T. Taniguchi, K. Honda. 2006. Evidence for licensing of IFN--induced IFN regulatory factor 1 transcription factor by MyD88 in Toll-like receptor-dependent gene induction program. Proc. Natl. Acad. Sci. USA 103: 15136-15141. [Abstract/Free Full Text]
25. Honda, K., H. Yanai, H. Negishi, M. Asagiri, M. Sato, T. Mizutani, N. Shimada, Y. Ohba, A. Takaoka, N. Yoshida, T. Taniguchi. 2005. IRF-7 is the master regulator of type-I interferon-dependent immune responses. Nature 434: 772-777. [Medline]
26. Honda, K., Y. Ohba, H. Yanai, H. Negishi, T. Mizutani, A. Takaoka, C. Taya, T. Taniguchi. 2005. Spatiotemporal regulation of MyD88-IRF-7 signalling for robust type-I interferon induction. Nature 434: 1035-1040. [Medline]
27. Hemmi, H., T. Kaisho, O. Takeuchi, S. Sato, H. Sanjo, K. Hoshino, T. Horiuchi, H. Tomizawa, K. Takeda, S. Akira. 2002. Small anti-viral compounds activate immune cells via the TLR7 MyD88-dependent signaling pathway. Nat. Immunol. 3: 196-200. [Medline]
28. Lee, J., T. H. Chuang, V. Redecke, L. She, P. M. Pitha, D. A. Carson, E. Raz, H. B. Cottam. 2003. Molecular basis for the immunostimulatory activity of guanine nucleoside analogs: activation of Toll-like receptor 7. Proc. Natl. Acad. Sci. USA 100: 6646-6651. [Abstract/Free Full Text]
29. Bauer, S., C. J. Kirschning, H. Hacker, V. Redecke, S. Hausmann, S. Akira, H. Wagner, G. B. Lipford. 2001. Human TLR9 confers responsiveness to bacterial DNA via species-specific CpG motif recognition. Proc. Natl. Acad. Sci. USA 98: 9237-9242. [Abstract/Free Full Text]
30. Krug, A., S. Rothenfusser, V. Hornung, B. Jahrsdorfer, S. Blackwell, Z. K. Ballas, S. Endres, A. M. Krieg, G. Hartmann. 2001. Identification of CpG oligonucleotide sequences with high induction of IFN-/ in plasmacytoid dendritic cells. Eur. J. Immunol. 31: 2154-2163. [Medline]
31. Tushinski, R. J., I. T. Oliver, L. J. Guilbert, P. W. Tynan, J. R. Warner, E. R. Stanley. 1982. Survival of mononuclear phagocytes depends on a lineage-specific growth factor that the differentiated cells selectively destroy. Cell 28: 71-81. [Medline]
32. Hume, D. A., S. Gordon. 1983. Optimal conditions for proliferation of bone marrow-derived mouse macrophages in culture: the roles of CSF-1, serum, Ca²⁺, and adherence. J. Cell. Physiol. 117: 189-194. [Medline]
33. Baetz, A., M. Frey, K. Heeg, A. H. Dalpke. 2004. Suppressor of cytokine signaling (SOCS) proteins indirectly regulate Toll-like receptor signaling in innate immune cells. J. Biol. Chem. 279: 54708-54715. [Abstract/Free Full Text]
34. Schroder, K., M. Lichtinger, K. M. Irvine, K. Brion, A. Trieu, I. L. Ross, T. Ravasi, K. J. Stacey, M. Rehli, D. A. Hume, M. J. Sweet. 2007. PU.1 and ICSBP control constitutive and IFN--regulated Tlr9 gene expression in mouse macrophages. J. Leukocyte Biol. 81: 1577-1590. [Abstract/Free Full Text]
35. Irvine, K. M., C. J. Burns, A. F. Wilks, S. Su, D. A. Hume, M. J. Sweet. 2006. A CSF-1 receptor kinase inhibitor targets effector functions and inhibits proinflammatory cytokine production from murine macrophage populations. FASEB J. 20: 1921-1923. [Abstract/Free Full Text]
36. Sester, D. P., A. Trieu, K. Brion, K. Schroder, T. Ravasi, J. A. Robinson, R. C. McDonald, V. Ripoll, C. A. Wells, H. Suzuki, et al 2005. LPS regulates a set of genes in primary murine macrophages by antagonizing CSF-1 action. Immunobiology 210: 97-107. [Medline]
37. Kerkmann, M., S. Rothenfusser, V. Hornung, A. Towarowski, M. Wagner, A. Sarris, T. Giese, S. Endres, G. Hartmann. 2003. Activation with CpG-A and CpG-B oligonucleotides reveals two distinct regulatory pathways of type I IFN synthesis in human plasmacytoid dendritic cells. J. Immunol. 170: 4465-4474. [Abstract/Free Full Text]
38. Shuai, K., C. Schindler, V. R. Prezioso, J. E. Darnell, Jr. 1992. Activation of transcription by IFN-: tyrosine phosphorylation of a 91-kD DNA binding protein. Science 258: 1808-1812. [Abstract/Free Full Text]
39. Gao, J. J., M. B. Filla, M. J. Fultz, S. N. Vogel, S. W. Russell, W. J. Murphy. 1998. Autocrine/paracrine IFN-alpha mediates the lipopolysaccharide-induced activation of transcription factor Stat1 in mouse macrophages: pivotal role of Stat1 in induction of the inducible nitric oxide synthase gene. J. Immunol. 161: 4803-4810. [Abstract/Free Full Text]
40. Kovarik, P., D. Stoiber, M. Novy, T. Decker. 1998. Stat1 combines signals derived from IFN- and LPS receptors during macrophage activation. EMBO J. 17: 3660-3668. [Medline]
41. Shuai, K., C. M. Horvath, L. H. Huang, S. A. Qureshi, D. Cowburn, J. E. Darnell, Jr. 1994. Interferon activation of the transcription factor Stat91 involves dimerization through SH2-phosphotyrosyl peptide interactions. Cell 76: 821-828. [Medline]
42. Rovida, E., A. Paccagnini, M. Del Rosso, J. Peschon, P. Dello Sbarba. 2001. TNF--converting enzyme cleaves the macrophage colony-stimulating factor receptor in macrophages undergoing activation. J. Immunol. 166: 1583-1589. [Abstract/Free Full Text]
43. Sester, D. P., S. J. Beasley, M. J. Sweet, L. F. Fowles, S. L. Cronau, K. J. Stacey, D. A. Hume. 1999. Bacterial/CpG DNA down-modulates colony stimulating factor-1 receptor surface expression on murine bone marrow-derived macrophages with concomitant growth arrest and factor-independent survival. J. Immunol. 163: 6541-6550. [Abstract/Free Full Text]
44. Tsujimura, H., T. Tamura, H. J. Kong, A. Nishiyama, K. J. Ishii, D. M. Klinman, K. Ozato. 2004. Toll-like receptor 9 signaling activates NF-B through IFN regulatory factor-8/IFN consensus sequence binding protein in dendritic cells. J. Immunol. 172: 6820-6827. [Abstract/Free Full Text]
45. Tamura, T., P. Tailor, K. Yamaoka, H. J. Kong, H. Tsujimura, J. O’Shea, H. Singh, K. Ozato. 2005. IFN regulatory factor-4 and -8 govern dendritic cell subset development and their functional diversity. J. Immunol. 174: 2573-2581. [Abstract/Free Full Text]
46. Zhang, J. J., U. Vinkemeier, W. Gu, D. Chakravarti, C. M. Horvath, J. E. Darnell, Jr. 1996. Two contact regions between Stat1 and CBP/p300 in interferon signaling. Proc. Natl. Acad. Sci. USA 93: 15092-15096. [Abstract/Free Full Text]
47. Ouchi, T., S. W. Lee, M. Ouchi, S. A. Aaronson, C. M. Horvath. 2000. Collaboration of signal transducer and activator of transcription 1 (STAT1) and BRCA1 in differential regulation of IFN- target genes. Proc. Natl. Acad. Sci. USA 97: 5208-5213. [Abstract/Free Full Text]
48. Zhang, J. J., Y. Zhao, B. T. Chait, W. W. Lathem, M. Ritzi, R. Knippers, J. E. Darnell, Jr. 1998. Ser727-dependent recruitment of MCM5 by Stat1 in IFN--induced transcriptional activation. EMBO J. 17: 6963-6971. [Medline]
49. Kim, S., T. Koga, M. Isobe, B. E. Kern, T. Yokochi, Y. E. Chin, G. Karsenty, T. Taniguchi, H. Takayanagi. 2003. Stat1 functions as a cytoplasmic attenuator of Runx2 in the transcriptional program of osteoblast differentiation. Genes Dev. 17: 1979-1991. [Abstract/Free Full Text]
50. Lau, J. F., J. P. Parisien, C. M. Horvath. 2000. Interferon regulatory factor subcellular localization is determined by a bipartite nuclear localization signal in the DNA-binding domain and interaction with cytoplasmic retention factors. Proc. Natl. Acad. Sci. USA 97: 7278-7283. [Abstract/Free Full Text]
51. Unlu, S., A. Kumar, W. R. Waterman, J. Tsukada, K. Z. Wang, D. L. Galson, P. E. Auron. 2007. Phosphorylation of IRF8 in a pre-associated complex with Spi-1/PU.1 and non-phosphorylated Stat1 is critical for LPS induction of the IL1B gene. Mol. Immunol. 44: 3364-3379. [Medline]
52. Blanco, J. C., C. Contursi, C. A. Salkowski, D. L. DeWitt, K. Ozato, S. N. Vogel. 2000. Interferon regulatory factor (IRF)-1 and IRF-2 regulate interferon -dependent cyclooxygenase 2 expression. J. Exp. Med. 191: 2131-2144. [Abstract/Free Full Text]
53. Salkowski, C. A., K. Kopydlowski, J. Blanco, M. J. Cody, R. McNally, S. N. Vogel. 1999. IL-12 is dysregulated in macrophages from IRF-1 and IRF-2 knockout mice. J. Immunol. 163: 1529-1536. [Abstract/Free Full Text]
54. Rouyez, M. C., M. Lestingi, M. Charon, S. Fichelson, A. Buzyn, I. Dusanter-Fourt. 2005. IFN regulatory factor-2 cooperates with STAT1 to regulate transporter associated with antigen processing-1 promoter activity. J. Immunol. 174: 3948-3958. [Abstract/Free Full Text]
55. Karaghiosoff, M., R. Steinborn, P. Kovarik, G. Kriegshauser, M. Baccarini, B. Donabauer, U. Reichart, T. Kolbe, C. Bogdan, T. Leanderson, et al 2003. Central role for type I interferons and Tyk2 in lipopolysaccharide-induced endotoxin shock. Nat. Immunol. 4: 471-477. [Medline]
56. Kamezaki, K., K. Shimoda, A. Numata, T. Matsuda, K. Nakayama, M. Harada. 2004. The role of Tyk2, Stat1 and Stat4 in LPS-induced endotoxin signals. Int. Immunol. 16: 1173-1179. [Abstract/Free Full Text]

This article has been cited by other articles:

				A. J. Fleetwood, H. Dinh, A. D. Cook, P. J Hertzog, and J. A. Hamilton GM-CSF- and M-CSF-dependent macrophage phenotypes display differential dependence on Type I interferon signaling J. Leukoc. Biol., August 1, 2009; 86(2): 411 - 421. [Abstract] [Full Text] [PDF]

				A. Larange, D. Antonios, M. Pallardy, and S. Kerdine-Romer TLR7 and TLR8 agonists trigger different signaling pathways for human dendritic cell maturation J. Leukoc. Biol., April 1, 2009; 85(4): 673 - 683. [Abstract] [Full Text] [PDF]

				C. M. Prele, E. A. Woodward, J. Bisley, A. Keith-Magee, S. E. Nicholson, and P. H. Hart SOCS1 Regulates the IFN but Not NF{kappa}B Pathway in TLR-Stimulated Human Monocytes and Macrophages J. Immunol., December 1, 2008; 181(11): 8018 - 8026. [Abstract] [Full Text] [PDF]

				A. Bugarcic, K. Hitchens, A. G Beckhouse, C. A Wells, R. B Ashman, and H. Blanchard Human and mouse macrophage-inducible C-type lectin (Mincle) bind Candida albicans Glycobiology, September 1, 2008; 18(9): 679 - 685. [Abstract] [Full Text] [PDF]

				K.-F. Kong, K. Delroux, X. Wang, F. Qian, A. Arjona, S. E. Malawista, E. Fikrig, and R. R. Montgomery Dysregulation of TLR3 Impairs the Innate Immune Response to West Nile Virus in the Elderly J. Virol., August 1, 2008; 82(15): 7613 - 7623. [Abstract] [Full Text] [PDF]

				C. T. Ranjith-Kumar, K. E. Duffy, J. L. Jordan, A. Eaton-Bassiri, R. Vaughan, S. A. Hoose, R. J. Lamb, R. T. Sarisky, and C. C. Kao Single-Stranded Oligonucleotides Can Inhibit Cytokine Production Induced by Human Toll-Like Receptor 3 Mol. Cell. Biol., July 15, 2008; 28(14): 4507 - 4519. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Schroder, K. Articles by Sweet, M. J. Search for Related Content PubMed PubMed Citation Articles by Schroder, K. Articles by Sweet, M. J. Pubmed/NCBI databases Gene GEO Profiles HomoloGene UniGene Substance via MeSH