Defective Interleukin (IL)-18-mediated Natural Killer and T Helper Cell Type 1 Responses in IL-1 Receptor-associated Kinase (IRAK)-deficient Mice

doi:10.1084/jem.189.7.1129

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© The Rockefeller University Press, 0022-1007/1999/4/1129/ $5.00
The Journal of Experimental Medicine, Volume 189, Number 7, April 5, 1999 1129-1138

Articles

Defective Interleukin (IL)-18–mediated Natural Killer and T Helper Cell Type 1 Responses in IL-1 Receptor–associated Kinase (IRAK)-deficient Mice

Palanisamy Kanakaraj^*, Karen Ngo^*, Ying Wu^*, Ana Angulo, Peter Ghazal, Crafford A. Harris, John J. Siekierka, Per A. Peterson, and Wai-Ping Fung-Leung^*

From ^* R.W. Johnson Pharmaceutical Research Institute, San Diego, California 92121; R.W. Johnson Pharmaceutical Research Institute, Raritan, New Jersey 08869; and the Department of Immunology and Molecular Biology, Division of Virology, Scripps Research Institute, La Jolla, California 92037

Abstract

Top
Abstract
Materials and Methods
Results
Discussion
References

Interleukin (IL)-18 is functionally similar to IL-12 in mediatingT helper cell type 1 (Th1) response and natural killer (NK)cell activity but is related to IL-1 in protein structure andsignaling, including recruitment of IL-1 receptor–associatedkinase (IRAK) to the receptor and activation of c-Jun NH₂-terminalkinase (JNK) and nuclear factor (NF)- ${kappa}$ B. The role of IRAK in IL-18–induced responses was studied in IRAK-deficientmice. Significant defects in JNK induction and partial impairmentin NF- ${kappa}$ B activation were found in IRAK-deficient Th1 cells, resulting in a dramatic decrease in interferon (IFN)- ${gamma}$ mRNA expression.In vivo Th1 response to Propionibacterium acnes and lipopolysaccharidein IFN- ${gamma}$ production and induction of NK cytotoxicity by IL-18were severely impaired in IRAK-deficient mice. IFN- ${gamma}$ productionby activated NK cells in an acute murine cytomegalovirus infectionwas significantly reduced despite normal induction of NK cytotoxicity.These results demonstrate that IRAK plays an important rolein IL-18–induced signaling and function.

Key Words: c-Jun NH₂-terminal kinase • inhibitor of nuclear factor ${kappa}$ B • nuclear factor ${kappa}$ B • interferon ${gamma}$ • murine cytomegalovirus

Address correspondence to Wai-Ping Fung-Leung, 3535 GeneralAtomics Ct., Suite 100, R.W. Johnson Pharmaceutical ResearchInstitute, San Diego, CA 92121. Phone: 619-450-2016; Fax: 619-450-2070; E-mail: wleung{at}prius.jnj.com

Abbreviations used: AP-1, activator protein 1; ES, embryonic stem; GST, glutathione S-transferase; ICE, IL-1β converting enzyme; I ${kappa}$ B, inhibitor of NF- ${kappa}$ B; IKK, I ${kappa}$ B kinase; IRAK, IL-1 receptor–associated kinase; JAK, Janus kinase; JNK, c-Jun NH₂-terminal kinase; MAP, mitogen-activated protein; MCMV, murine cytomegalovirus; NF, nuclear factor; STAT, signal transducer and activator of transcription; TRAF, TNF receptor–associated factor.

Interleukin (IL)-18 (previously known as IFN- ${gamma}$ –inducing factor, or IGIF) was cloned from the liver of mice primed with Propionibacterium acnes, followed by challenge with LPS (1). IL-18 induces production of IFN- ${gamma}$ from Th1 cells and NKcells (2–5). In addition, IL-18 enhances NK cell cytotoxicityand also synergizes with IL-12 in potentiating IFN- ${gamma}$ productionand NK cell cytotoxicity (1, 3, 4). Thus, cellular responsesto IL-18 are similar to the biological functions known to beelicited by IL-12 (6).

Despite functional similarities, IL-12 and IL-18 differ in their protein structure and exert these overlapping and synergisticbiological effects via different mechanisms. IL-12 mediatesTh1 responses and IFN- ${gamma}$ production via activation of Janus kinases(JAKs),¹ JAK2 and TYK2 (7), and transcription factors calledsignal transducer and activator of transcription (STAT), STAT3and STAT4 (8). STAT4-deficient mice are defective in mountingTh1 responses and IFN- ${gamma}$ production (9, 10). Stimulation withIL-18 results in activation of c-Jun NH₂-terminal kinase (JNK)and transcription factor nuclear factor (NF)- ${kappa}$ B (2, 4).

IL-18 is similar in tertiary structure to proteins of the IL-1 family (11). Similar to IL-1β, IL-18 is synthesized asan inactive precursor protein and is cleaved to the active form by IL-1β–converting enzyme (ICE, also named caspase1; references 12, 13). Cleavage of IL-18 by ICE is essentialfor the biological effects of IL-18. ICE-deficient mice exhibit defects similar to those observed in IL-18^–/– mice,such as reduced IFN- ${gamma}$ production in response to LPS injection(3, 12, 13). The IL-18 receptor was originally identified asIL-1 receptor–related protein (IL-1Rrp; references 14,15). Receptors for IL-1, IL-18, and the recently identifiedmammalian Toll-like receptors (16) are evolutionarily conserved and homologous to the Drosophila protein Toll (17). Toll mediatesactivation of Dorsal, an NF- ${kappa}$ B–like molecule, via theserine threonine kinase Pelle and the adapter protein Tube(17, 18). The IL-1 signaling pathway in mammals is similarto the Toll pathway. NF- ${kappa}$ B activation by IL-1 requires the interactionof the Pelle-like kinase IL-1 receptor– associated kinase(IRAK) with the IL-1 receptor complex via the adapter proteinMyD88 (19–21). IL-18 also triggers phosphorylation ofIRAK and its recruitment to the IL-18 receptor complex (4,22). However, IL-1 and IL-18 act on different cell types andlead to divergent cellular responses. For example, IL-18 hasbeen implicated primarily in inducing IFN- ${gamma}$ from NK and Th1 cells(1–5), whereas IL-1 is a potent inducer of IL-6 fromfibroblasts and macrophages during inflammation (23–25).We have recently demonstrated that IRAK is required for optimalinduction of IL-1 signaling, including JNK, p38, and NF- ${kappa}$ B activation(25). Defective IL-1 signaling in IRAK-deficient fibroblastsresults in impaired IL-6 induction (25). Although IL-18 signalingis known to involve activation of JNK and NF- ${kappa}$ B (2, 4), detailsof IL-18 signaling have not been well characterized. It isalso unclear whether IL-18 uses IRAK in pathways similar toIL-1 signaling to elicit distinct cellular responses. To determinethe role of IRAK in IL-18–mediated responses, we analyzedIL-18–induced signaling and function in IRAK-deficientmice.

In this report we showed that IRAK was essential for IL-18–mediatedactivation of JNK and was also involved in NF- ${kappa}$ B activation.Signaling defects in IRAK-deficient Th1 cells resulted in adramatic decrease in IFN- ${gamma}$ expression. Serum IFN- ${gamma}$ increase inresponse to P. acnes and LPS treatment was severely impaired.IRAK-deficient mice also exhibited defects in NK IFN- ${gamma}$ productionin an acute murine cytomegalovirus (MCMV) infection. NK cellcytotoxicity induced by IL-18 was defective, although its inductionwas normal in MCMV infection. These results suggest that IRAKplays an important role in IL-18–mediated signaling andfunction.

Materials and Methods

Top
Abstract
Materials and Methods
Results
Discussion
References

Generation of IRAK-deficient Mice.
The mouse IRAK gene in embryonic stem (ES) cells was disruptedby homologous recombination as described in our previous report(25). In brief, the mouse IRAK gene was disrupted by replacementof a 940-bp region covering exons 5–7 of the gene witha neomycin resistance gene. Chimeric mice were generated fromembryos injected with ES cells. Germline mice were obtainedfrom breeding of chimeric male mice with C57BL/6J females.Because the IRAK gene is on X chromosome (sequence data availablefrom EMBL/GenBank/ DDBJ under accession No. U52112) and theES cell line was derived from a male embryo, all the germlinefemale mice were heterozygous for the disrupted IRAK gene.IRAK-deficient male mice carrying only the disrupted IRAK genewere obtained from breeding of heterozygous female mice withwild-type littermates. IRAK-deficient female mice were obtainedfrom breeding of heterozygous females with IRAK-deficient males.

Phenotypic Analysis of T Cells.
Thymocytes and splenocytes were stained with CD4- and CD8-specificantibodies (PharMingen). Enriched CD4⁺ T cells before and after5 d of differentiation were stained with antibodies specificfor CD25 and CD44 (PharMingen). Cells after antibody stainingwere analyzed using a FACScan^TM (Becton Dickinson).

Preparation of Th1/Th2 Cells.
CD4⁺ T cells were purified from lymph node and spleen cellsby depletion of B cells and CD8⁺ T cells using guinea pig andrabbit complements and a combination of antibodies from hybridomalines J11d, 28-16-8s, and 3-168. Purity of CD4⁺ T cells indifferent preparations was $~$ 90%. Enriched CD4⁺ T cells wereactivated with immobilized anti-CD3 (PharMingen), which wascoated overnight onto 6-well plates at 5 µg/ml. Differentiationof T cells towards Th1 cells was triggered by addition of 5ng/ml IL-12 (R&D Systems) and 5 µg/ml anti–IL-4(PharMingen) in RPMI medium with 10% FCS. Th2 cell differentiationwas driven by supplementing culture medium with 5 ng/ml IL-4(R&D Systems) and 5 µg/ml of anti–IFN- ${gamma}$ plusanti–IL-12 (PharMingen). The cytokine profile of Th1 or Th2 cells was determined by plating the cells at 2 x 10⁵ cell/well in 96-well plates that were precoated overnight with 5 µg/ml anti-CD3. Culture supernatants were collected 24 h later forcytokine detection by ELISA.

Cell Stimulation.
After 5 d of differentiation, Th1 cells were washed once withserum-free RPMI medium and starved for 3 h before stimulation.Cells were treated with different stimuli at 37°C. Thedifferent stimuli used in the assays include: IL-18 (PeproTech,Inc.), IL-12 (R&D Systems); IL-1β (R&D Systems); TNF- ${alpha}$ (Genzyme Corp.); PMA and ionomycin (Sigma Chemical Co.).After stimulation, cells were lysed for 20 min at 4°C with lysis buffer (100 µl/5 x 10⁶ cells) containing 10 mMHepes, pH 7.5, 150 mM NaCl, 1% NP-40, 1 mM Na₃VO₄, 10% glycerol, 1 µg/ml leupeptin, 1 µg/ml aprotinin, 1 mM PMSF,and 1 mM EDTA. Cell lysates for kinase assays and Western blotswere collected after centrifugation of samples at 14,000 rpmfor 10 min at 4°C.

In Vitro Kinase Assay.
Cell lysates (5 x 10⁶ cells in 100 µl of lysis buffer)were immunoprecipitated with JNK1 kinase antibody (Santa CruzBiotechnology). An in vitro kinase assay was performed usingglutathione S-transferase (GST)–c-Jun (Santa Cruz Biotechnology)as a substrate in a reaction buffer containing 25 mM Hepes,pH 7.4, 25 µM ATP, 10 mM MgCl₂, 1 µg GST–c-Jun, and 10 µCi [ ${gamma}$ -³²P]ATP for 30 min at 37°C. Samplesafter kinase assays were separated on 10% SDS-PAGE, transferredto nitrocellulose filters (MSI), and then subjected to autoradiography.Radioactivity of the phosphorylated c-Jun bands were quantitatedby PhosphorImager (Molecular Dynamics Inc.). JNK1 protein onblotted filters was detected with a JNK1-specific antibody (SantaCruz Biotechnology).

Western Blotting.
Western blot analyses were carried out as previously described(26). For detection of I ${kappa}$ B- ${alpha}$ protein levels, cell lysates (10⁵cells/sample) were separated on 10% SDS-PAGE (Novex) and transferredto nitrocellulose filters. Filters were immunoblotted with anI ${kappa}$ B- ${alpha}$ –specific rabbit antibody (Santa Cruz Biotechnology)and detected with horseradish peroxidase–conjugated rabbitIgG and enhanced chemiluminescence (Amersham Pharmacia Biotech).Filters were then stripped by soaking in 0.1 M glycine/HCl,pH 2.6, for 30 min and reprobed with an ERK-2– specificantibody (Santa Cruz Biotechnology) for normalization.

NF- ${kappa}$ B Mobility Shift Assay.
Cells after treatment with different stimuli were pelleted andtaken up in 500 µl ice-cold buffer A (10 mM Hepes, pH7.9, 10 mM KCl, 100 µM EDTA, 100 µM EGTA, 1 mMdithiothreitol, 500 µM PMSF) and kept on ice for 15 min.Samples were then added with 30 µl of 10% NP-40 followedby centrifugation at 14,000 rpm for 30 s. Nuclear pellets werewashed once with buffer A and lysed in 50 µl buffer B (20 mM Hepes, pH 7.9, 400 mM NaCl, 1 mM EDTA, 1 mM EGTA, 1mM dithiothreitol, 1 mM PMSF) for 30 min at 4°C. Nuclearextracts were collected after centrifugation of the samples at 14,000 rpm for 10 min. Protein concentration was determined by the BCA method (Pierce Chemical Co.). The consensus double-strandedoligonucleotide for NF- ${kappa}$ B binding (Santa Cruz Biotechnology)was labeled using [ ${gamma}$ -³²P]ATP and T4 polynucleotide kinase. Nuclearbinding reactions were carried out for 30 min at room temperaturein a 20 µl mixture containing 10 µg nuclear extractand 0.5 ng ³²P-labeled oligonucleotide probe (100,000 cpm)in buffer C (5 mM Hepes, pH 7.9, 5 mM MgCl₂, 1 mM EDTA, 10%glycerol, and 1 µg/ml poly[dI-dC]). Oligonucleotide–proteincomplexes were separated on 6% polyacrylamide/ 0.5x TBE gelsand detected by autoradiography.

Northern Blot Analysis.
Total RNA was extracted from cells or spleens with RNAzol (Tel-TestInc.). RNA was separated on 1% agarose-formaldehyde gels andtransferred to nylon membranes (Amersham Pharmacia Biotech).Filters were hybridized to cDNA probes specific for IFN- ${gamma}$ (Clontech)and IL-18 (Research Genetics, Inc.). cDNA probes were labeledwith ${alpha}$ -[³²P]dCTP (Amersham Pharmacia Biotech) by random priming(Boehringer Mannheim). Radioactive signals were detected byautoradiography. Filters were then stripped by boiling in 0.1%SDS and rehybridized with glycerol-3-phosphate dehydrogenasecDNA probe (Clontech) for normalization.

Cytokine Detection.
IFN- ${gamma}$ and IL-4 in serum samples and culture supernatants weredetermined by using commercially available ELISA kits (Genzyme)and recombinant cytokines were used as standards provided bythe manufacturer.

Cell Proliferation Assay.
Th1 cells were plated in 96-well plates at 10⁵/well and treatedwith different cytokines for 24 h. [³H]thymidine (1 µCi/well)was then added for 16 h, and radioactivity incorporated in dividingcells was measured using a Topcount Microplate ScintillationCounter (Packard).

In Vivo Th1 Response.
Mice were injected intraperitoneally with PBS as controls orPBS with 2 mg of heat-killed P. acnes (Van Kempen Group, Inc.).7 d later, control mice were injected intravenously with PBS,whereas P. acnes–primed mice were injected with 1 µgLPS (Sigma Chemical Co.). Mice were bled 6 h after LPS challenge,and serum IFN- ${gamma}$ levels were measured by ELISA (Genzyme). TotalRNA was extracted from spleen samples for Northern blot analysis.

NK Cytotoxic Assay.
Mice were injected intraperitoneally daily with PBS alone ascontrols or PBS containing 1 µg IL-18 or 200 µgpoly(I):poly(C) (Sigma Chemical Co.) for 2 d. Spleen cellsprepared from these mice were incubated with ⁵¹Cr-labeled YAC-1target cells for 4 h at 37°C at different E/T ratios. After4 h of incubation, ⁵¹Cr released from target cells was countedusing a gamma counter (Packard). Specific lysis was calculatedas: (measured ⁵¹Cr release – spontaneous ⁵¹Cr release)/(maximum⁵¹Cr release – spontaneous ⁵¹Cr release) x 100. Maximumrelease was obtained by counting acid-lysed target cells. Spontaneousrelease was obtained by incubating target cells in the absenceof effector cells.

MCMV Infections.
The Smith strain of MCMV was obtained from the American TypeCulture Collection (VR-1399). MCMV stocks were prepared inNIH 3T3 murine fibroblasts, and determination of viral titerswas carried out by a standard plaque assay (27). Mice wereintraperitoneally injected with 10⁸ PFU of tissue culture–propagatedMCMV in 400 µl DMEM. Animals were killed on day 3 afterinoculation. Blood sera for cytokine detection were collectedby bleeding mice daily starting from day 0 before viral inoculation.Spleens were collected after 71 h of infection for NK cytotoxicassays and RNA extraction.

Results

Top
Abstract
Materials and Methods
Results
Discussion
References

Normal Differentiation of Th1 and Th2 Cells in the Absence of IRAK.
IL-18 by itself has no effect on Th1 differentiation but cansynergize IL-12–driven Th1 development (4). In differentiatedhelper T cells, IL-18 exerts its biological effects only onTh1 cells but not on Th2 cells (4). Since IRAK is involvedin IL-18 signaling (4, 22), we examined helper T cell developmentand phenotype in IRAK-deficient mice. Development of T cellsin the thymus and distribution of mature CD4⁺ and CD8⁺ T cellsin the primary and secondary lymphoid organs of IRAK-deficientmice appeared to be normal (Fig. 1 A). The vast majority ofCD4⁺ T cells were characterized as CD25^loCD44^lo naive phenotypeand were comparable to the cells harvested from control wild-typemice (Fig. 1 B). Th1 and Th2 cells were prepared by in vitrodifferentiation of CD4⁺ T cells from IRAK-deficient and wild-typemice. CD4⁺ T cells were enriched from lymph node cells andsplenocytes by antibody and complement depletion as describedin Material and Methods. Enriched CD4⁺ T cells were activatedwith immobilized anti-CD3 and differentiation towards Th1 cellswas triggered by coculture with IL-12 and anti–IL-4.Th2 cell differentiation was driven by IL-4 and anti–IFN- ${gamma}$ plus anti–IL-12. Activation of IRAK-deficient CD4⁺ Tcells appeared to be normal, as indicated by the upregulationof the activation marker CD25 and the memory T cell markerCD44 (Fig. 1 B). Numbers of blasting T cells after 5 d of differentiation were similar between IRAK-deficient and wild-type T cells (data not shown), suggesting normal proliferation of activatedIRAK-deficient T cells. Cytokines expressed by T cells after5 d of differentiation were characterized by ELISA. Similarto wild-type Th1 cells, IRAK-deficient Th1 cells secreted predominantlyIFN- ${gamma}$ , whereas IL-4 was undetectable (Fig. 1 C). IRAK-deficientTh2 cells also showed a typical Th2 cytokine profile similarto that of wild-type Th2 cells, with high amounts of IL-4 butminimal levels of IFN- ${gamma}$ (Fig. 1 C). Our data suggest that IRAK-deficientT cells can differentiate into Th1 or Th2 effector cells.

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Figure 1 IRAK is dispensable for T cell development and Th1/Th2 differentiation. (A) CD4⁺ and CD8⁺ T cell populations in the thymuses and the spleens of IRAK-deficient [IRAK(–)] and wild-type mice were analyzed in flow cytometry. Immature CD4⁺ CD8⁺ double positive T cells in thymuses are also shown. (B) CD4⁺ T cells purified from the spleens and lymph nodes of IRAK-deficient [IRAK(–)] and wild-type mice were stimulated in anti-CD3 coated plates in the presence of IL-12 and anti–IL-4 for Th1 differentiation or IL-4 and anti–IFN- ${gamma}$ plus anti–IL-12 for Th2 differentiation. Enriched CD4⁺ T cells before (broken line) and after (solid line) 5 d of stimulation were stained with antibodies specific for CD25 and CD44 for flow cytometry analysis. (C) After 5 d of Th1 or Th2 differentiation, cells were washed and restimulated overnight with anti-CD3 antibody. IFN- ${gamma}$ and IL-4 levels in culture supernatants were determined by ELISA.

Impaired JNK Activation by IL-18 in IRAK-deficient Cells.
The stress-activated protein kinase (SAPK) family of mitogen-activatedprotein (MAP) kinases JNK and p38 are rapidly activated by proinflammatorycytokines such as IL-1 and TNF- ${alpha}$ (24, 25, 28). IL-18 stimulationof Th1 cells also results in JNK activation (2). JNK plays arole in induction of activator protein (AP)-1–dependentgenes via phosphorylation of the transcription factor c-Jun(28, 29). We have shown previously that IRAK-deficient fibroblastsare defective in IL-1–mediated JNK activation (25). Todetermine the role of IRAK in IL-18–induced JNK activation,JNK activity in Th1 cells was studied by immunoprecipitatingJNK1 with a specific antibody followed by an in vitro kinaseassay using the GST–c-Jun protein as a substrate. Activationof JNK was minimal in IL-18–treated IRAK-deficient Th1cells as opposed to the significant JNK activation observedin wild-type cells (Fig. 2). In contrast, TNF- ${alpha}$ induced similarlevels of JNK activity in both wild-type and IRAK-deficientTh1 cells, whereas IL-1β did not have any effects on eithersamples (Fig. 2). IL-18 and IL-1 have been suggested to acton Th1 and Th2 cells, respectively, to induce signaling and cellular responses (4). In our studies, Th1 cells do not respond to IL-1β in JNK activation and this is consistent witha previous observation (4), which suggested that IL-1 does notinduce signaling in Th1 cells due to the lack of IL-1 receptor expression. Our results indicate that the defect in JNK activationobserved in IRAK-deficient Th1 cells is IL-18 specific.

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Figure 2 Impaired IL-18–mediated JNK activation in IRAK-deficient Th1 cells. IRAK-deficient [IRAK(–)] and wild-type Th1 cells were stimulated with medium alone, IL-1β (10 ng/ml), TNF- ${alpha}$ (50 ng/ml), or different concentrations of IL-18 as indicated for 15 min. Cell lysates were immunoprecipitated with a JNK-specific antibody. In vitro JNK kinase assay was performed using GST–c-Jun as a substrate. Amounts of JNK protein in the immune complexes were detected by Western blotting using a JNK-specific antibody.

IRAK Is Dispensable for NF- ${kappa}$ B Activation by IL-18.
IL-18 binding to its receptor mediates activation of NF- ${kappa}$ B (4,22). In unstimulated cells, NF- ${kappa}$ B is present in the cytoplasmas an inactive complex sequestered by its inhibitory partners, I ${kappa}$ B (30). Upon activation, I ${kappa}$ B proteins are phosphorylated byI ${kappa}$ B kinases IKK1 and IKK2, and subsequently degraded by proteosomesto allow nuclear translocation and activation of NF- ${kappa}$ B (30–32).To determine the role of IRAK in IL-18–induced NF- ${kappa}$ B activation,I ${kappa}$ B- ${alpha}$ protein levels were determined in Th1 cells stimulatedwith IL-18 for different time courses (Fig. 3 A). Reduced levelsof I ${kappa}$ B- ${alpha}$ due to protein degradation were observed in both wild-typeand IRAK-deficient cells after IL-18 treatment (Fig. 3 A).Maximum degradation of I ${kappa}$ B protein occurred 15 min after stimulationand returned to 80% of original levels within 60 min of stimulation.The extent of I ${kappa}$ B- ${alpha}$ protein degradation mediated by IL-18 appearedto be less in IRAK-deficient Th1 cells as compared with thatin wild-type cells. Similar results were observed when wild-typeand IRAK-deficient Th1 cells were stimulated with differentconcentrations of IL-18 (data not shown). This result was further confirmed by NF- ${kappa}$ B DNA binding activity in nuclear extractsdetermined by mobility shift assay. IL-18–induced NF- ${kappa}$ Bactivation in both IRAK-deficient and wild-type cells, butNF- ${kappa}$ B DNA binding activity was slightly lower in IRAK-deficientcells than in wild-type cells (Fig. 3 B). Stimulation withTNF- ${alpha}$ or phorbol ester plus ionomycin induced comparable levelsof NF- ${kappa}$ B activation in both cell types, indicating that thepartial defect in NF- ${kappa}$ B activation observed in IRAK-deficientcells is restricted to IL-18 stimulation. These results suggestthat involvement of IRAK in IL-18–mediated NF- ${kappa}$ B activationis dispensable.

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Figure 3 Reduced NF- ${kappa}$ B activation by IL-18 in IRAK-deficient Th1 cells. (A) Reduced degradation of I ${kappa}$ B- ${alpha}$ in IRAK-deficient cells. IRAK-deficient [IRAK(–)] and wild-type cells were stimulated with IL-18 (50 ng/ml) for different time courses as indicated. Cell lysates were prepared and separated on SDS-PAGE. I ${kappa}$ B- ${alpha}$ was detected by Western blot analysis using an I ${kappa}$ B- ${alpha}$ –specific antibody. Amounts of protein loading were determined by probing the same filter with antibody specific for ERK-2. (B) Reduced NF- ${kappa}$ B activation by IL-18 in IRAK-deficient cells. Cells were stimulated with IL-18 (50 ng/ml), TNF- ${alpha}$ (50 ng/ml), or PMA (50 ng/ml) plus ionomycin (0.125 µM) for 30 min. Nuclear extracts were prepared and incubated with ³²P-labeled NF- ${kappa}$ B specific double-stranded oligonucleotide. The NF- ${kappa}$ B DNA complex was separated on 6% polyacrylamide gel in 0.5% Tris-borate-EDTA.

IRAK Is Required for IL-18–induced IFN- ${gamma}$ Production.
IL-18 induces IFN- ${gamma}$ production from Th1 cells (1, 5). Stimulationof Th1 cells with a combination of IL-18 and IL-12 resultsin synergistic induction of IFN- ${gamma}$ production (4). To determinewhether IRAK is required for induction of IFN- ${gamma}$ by IL-18 itselfor in combination with IL-12, IFN- ${gamma}$ mRNA expression was determinedby Northern blot analysis. IFN- ${gamma}$ was significantly induced byIL-18 in wild-type cells but its induction in IRAK-deficientcells was minimal (Fig. 4 A). A suboptimal dose of IL-12 was used in our experiments, which induced minimal amounts ofIFN- ${gamma}$ , and no difference was observed between IRAK-deficientand wild-type cells. Synergistic induction of IFN- ${gamma}$ expressionby a combination of IL-18 and IL-12 was substantially decreasedin IRAK-deficient cells as compared with wild-type cells. Thisresult shows that IRAK is required for optimal induction ofIFN- ${gamma}$ by IL-18.

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Figure 4 Defective induction of IFN- ${gamma}$ production in IRAK-deficient mice. (A) Defective IFN- ${gamma}$ mRNA expression induced by IL-18 in IRAK-deficient Th1 cells. IRAK-deficient [IRAK(–)] and wild-type Th1 cells were stimulated with IL-18 (50 ng/ml), IL-12 (10 ng/ml), or a combination of IL-18 and IL-12 for 2 h. Total RNA was prepared from the cells and IFN- ${gamma}$ expression was determined by Northern blot analysis using ³²P-labeled IFN- ${gamma}$ cDNA probe. The blots were stripped and hybridized to glycerol-3-phosphate dehydrogenase (G3PDH) cDNA for normalization. (B) Reduced induction of IFN- ${gamma}$ production in P. acnes–primed and LPS-challenged IRAK-deficient mice. IRAK-deficient [IRAK(–)] and wild-type mice were intraperitoneally injected with 2 mg of heat-killed P. acnes. Mice were intravenously injected with 1 µg LPS on day 7. Serum samples were collected 6 h after LPS challenge and levels of IFN- ${gamma}$ in sera were determined by ELISA. (C) Total spleen RNA was prepared from P. acnes– and LPS–treated mice. IFN- ${gamma}$ expression was determined by Northern blot hybridization using ³²P-labeled IFN- ${gamma}$ cDNA probe. The blot was stripped and hybridized with IL-18 cDNA probe.

It has been demonstrated that treatment with LPS in P. acnes–sensitizedmice results in a significant increase in serum IFN- ${gamma}$ (33).IL-18–deficient mice exhibited a minimal increase in serumIFN- ${gamma}$ under these conditions (3). To determine the role of IRAKin IL-18–dependent IFN- ${gamma}$ production in vivo, IRAK-deficientmice were tested in this experimental system. Mice were injectedintraperitoneally with heat-killed P. acnes and 7 d later wereinjected intravenously with LPS. IFN- ${gamma}$ in the serum was detectedby ELISA 6 h after LPS treatment. Serum IFN- ${gamma}$ levels were significantlylower in IRAK-deficient mice as compared with wild-type animals(Fig. 4 B). Consistent with these data, IFN- ${gamma}$ mRNA expressionin the spleen was substantially reduced in IRAK-deficient mice.In contrast, induction of IL-18 mRNA expression was comparablebetween wild-type and IRAK-deficient animals (Fig. 4 C). Theseresults suggest that the reduced IFN- ${gamma}$ production in IRAK-deficientmice is not due to a change in IL-18 levels but rather originatedfrom defects in IL-18 signaling.

Decreased Proliferation of IRAK-deficient Th1 Cells.
Similar to induction in IFN- ${gamma}$ production, proliferation ofTh1 cells was also enhanced by IL-18 or IL-12, and synergized by the combination of both (4). The effect of IL-18 and its synergism with IL-12 on proliferation of IRAK-deficient Th1cells was studied. Wild-type and IRAK-deficient Th1 cells weretreated with different concentrations of IL-18, IL-12, or IL-18plus IL-12. Proliferation of Th1 cells after 24 h of stimulationwas determined by [³H]thymidine uptake. As shown in Fig. 5,proliferation of wild-type Th1 cells was significantly enhancedby IL-18 in a dose-dependent manner, whereas the effect of IL-18on proliferation of IRAK-deficient cells was minimal. At concentrationsas low as 2 ng/ml, IL-12 stimulated proliferation of both wild-typeand IRAK-deficient cells to maximal extent. Combination of IL-18and IL-12 resulted in a synergistic proliferative responsein both cell types, and no significant difference was observed.Consistent with the defects shown in IFN- ${gamma}$ expression, IRAK-deficientcells are also impaired in proliferative response to IL-18,confirming the role of IRAK in IL-18–mediated cellularresponses.

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Figure 5 Defective IL-18–induced proliferation of IRAK-deficient Th1 cells. Th1 cells (10⁵ cells /well) were plated on a 96-well plate and cultured in RPMI medium with the indicated concentrations of IL-18, IL-12, or IL-18 plus IL-12 for 24 h. Cell proliferation was determined by [³H]thymidine incorporation.

Defective Induction of NK Cell Activity by IL-18 in IRAK-deficient Mice.
IL-18 has been shown to enhance NK cell cytotoxicity (1). ReducedNK activity was reported in IL-18– deficient mice (3).To determine whether IRAK is involved in IL-18–inducedNK activity, mice were injected intraperitoneally with IL-18for 2 d consecutively, and NK activity in splenocytes was assayedusing ⁵¹Cr-labeled YAC-1 as target cells. Basal NK cell activitiesin PBS injected wild-type and IRAK-deficient mice were comparable(Fig. 6). IL-18 injection resulted in significant increase inNK activity in wild-type animals but its effect in IRAK-deficientmice was minimal (Fig. 6). However, injection of the double-stranded RNA poly(I):poly(C), an inducer of IFNs, resulted in a pronouncedNK activity in both IRAK-deficient and wild-type animals (Fig.6), indicating that IRAK is required specifically for IL-18–mediatedinduction of NK cytotoxic activity.

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Figure 6 Impaired IL-18–induced NK cytotoxicity in IRAK-deficient mice. IRAK-deficient [IRAK(–)] and wild-type mice were injected intraperitoneally with PBS, 1 µg IL-18, or 200 µg poly(I):poly(C) for 2 d consecutively. Spleen cells were assayed for NK cytotoxic activity against ⁵¹Cr-labeled YAC-1 target cells.

IRAK Is Essential for MCMV-induced IFN- ${gamma}$ Production but Not for NK Cell Cytotoxicity.
NK cells are the major effector cells in the early defenseagainst viral infections. Both NK cytotoxicity and IFN- ${gamma}$ productionby NK cells are induced in mice upon MCMV infection (34). IL-12has been shown to be responsible for induction of IFN- ${gamma}$ in NKcells (35), whereas possible roles of IL-18 in NK activitiesduring MCMV infection have not been reported. IRAK-deficientmice were infected with MCMV to study the involvement of IRAKin NK activity during viral infection. Splenocytes obtainedfrom mice on day 3 of MCMV infection were assayed for NK cytolyticactivity using ⁵¹Cr- labeled YAC-1 cells as targets. Dramaticincrease in NK cytotoxicity was observed in both MCMV-infectedwild-type and IRAK-deficient mice and no significant differencewas found between the two types of mice (Fig. 7 A). IFN- ${gamma}$ producedby NK cells during MCMV infection can be detected as an increasein serum IFN- ${gamma}$ levels. Kinetics of IFN- ${gamma}$ increase in sera duringthe first 3 d of MCMV infections was studied. In both wild-typeand IRAK-deficient mice, IFN- ${gamma}$ levels peaked at 45 h of infection(Fig. 7 B). However, maximal IFN- ${gamma}$ levels in IRAK-deficientmice were significantly lower than those in wild-type control mice (Fig. 7 B). Similar results were obtained in studies of IFN- ${gamma}$ mRNA expression. IFN- ${gamma}$ mRNA in the spleens was undetectablein uninfected mice but was induced significantly in MCMV infectedmice (Fig. 7 C). IFN- ${gamma}$ mRNA induced by MCMV was less significantin IRAK-deficient mice than that in wild-type mice. IL-18 expressionin response to MCMV infection was also studied. IL-18 mRNA was expressed at low levels in the spleens of uninfected miceand was induced strongly on day 3 of MCMV infection (Fig. 7C). IL-18 expression in IRAK-deficient mice was comparableto that in wild-type mice under healthy and viral-infectedconditions (Fig. 7 C). Thus, impairment in viral-induced IFN- ${gamma}$ production in IRAK-deficient mice is not due to the levelsof IL-18 expression, suggesting that other mechanisms, suchas IL-18 signaling, may be responsible for the defects.

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Figure 7 Reduced MCMV-induced IFN- ${gamma}$ production but normal NK cell cytotoxicity in IRAK-deficient mice. IRAK-deficient [IRAK(–)] and wild-type mice were injected intraperitoneally with 10⁸ PFU of MCMV. (A) Spleen cells from mice after 71 h of infection were assayed for NK cytotoxicity against ⁵¹Cr-labeled YAC-1 target cells. (B) IFN- ${gamma}$ levels in sera collected at 35, 45, and 71 h of MCMV infection were determined by ELISA. (C) Expression of IFN- ${gamma}$ mRNA in the spleens of infected mice after 71 h of MCMV injection was determined by Northern blot hybridization using ³²P- labeled specific IFN- ${gamma}$ cDNA probe.

	Discussion

Top Abstract Materials and Methods Results Discussion References

Role of IRAK in IL-18 Signaling Pathways.
We have demonstrated IL-18 signaling defects in IRAK-deficientTh1 cells. Impairment is significant in JNK activation butmuch less obvious in NF- ${kappa}$ B induction. The partial activationof NF- ${kappa}$ B suggests that other mechanisms can compensate forthe function of IRAK. However, the role of IRAK in JNK activationis essential. We have previously reported that IRAK-deficientfibroblasts are defective in both NF- ${kappa}$ B and JNK/p38 pathwaysinduced by IL-1 (25). The defects in IL-18 signaling that weobserved here are similar to the defects in IL-1 signaling(25). Impairment in NF- ${kappa}$ B activation can be overcome by highconcentrations of IL-1, but similar treatment cannot correctdefects in JNK activation (25). Taken together, our resultssuggest that IRAK is used similarly by both IL-18 and IL-1in mediating intracellular signaling.

IL-1 signaling leading to NF- ${kappa}$ B activation has been relativelywell characterized. Upon IL-1 binding to its receptor, IRAKis rapidly recruited to the receptor complex via MyD88 (20).Activated IRAK interacts with TNF receptor–associatedfactor (TRAF)6, which in turn activates NF- ${kappa}$ B–inducingkinase (NIK) (36, 37). NIK is involved in the NF- ${kappa}$ B pathwayby activating I ${kappa}$ B kinases (IKKs) (31, 32, 38, 39). ActivatedIKKs phosphorylate I ${kappa}$ B for degradation, allowing nuclear translocationof NF- ${kappa}$ B for gene induction (30). However, details of IL-1–mediatedsignaling leading to JNK activation are still unclear. It hasbeen reported that only MyD88 but not TRAF6 is essential for JNK activation (40). Since IRAK is positioned between MyD88and TRAF6 in the signaling cascade, IRAK could be the bifurcatingmolecule for both NF- ${kappa}$ B and JNK pathways. IL-18 stimulationalso induces the stress-activated MAP kinase JNK (2). The defectsin JNK activation in IRAK-deficient cells indicate that IRAKis essential for JNK activation but intermediary moleculeslinking IRAK to JNK have not been identified.

Recent reports on IL-1 signaling also suggest additional complexityand divergence in this pathway. In addition to IRAK, otherproteins, including IRAK homologue IRAK2, are reported to interactwith the IL-1 receptor (19, 41). IRAK2 also interacts withMyD88 and TRAF6 (19). A dominant negative form of IRAK2 mutantblocks MyD88-induced NF- ${kappa}$ B activation (19). Although overexpressionof IRAK in transfection studies has been reported to activate NF- ${kappa}$ B but not JNK (42), our studies demonstrate that IRAK isessential for IL-18–mediated activation of JNK but itsrole in NF- ${kappa}$ B pathway is less critical. In the absence of IRAK,NF- ${kappa}$ B activation can still occur, possibly mediated by otherrelated kinases such as IRAK2. The relative role of IRAK andIRAK2 in inducing JNK and NF- ${kappa}$ B downstream of MyD88 is stillunclear and the involvement of IRAK2 in IL-18 signaling remainsto be elucidated.

Defect in IL-18–mediated Functions in the Absence of IRAK.
IL-18 alone does not support Th1 differentiation, but it can potentiate Th1 development driven by IL-12 (4). In differentiatedTh1 cells, IFN- ${gamma}$ production can be induced by IL-18 or IL-12alone, and this effect can be further synergized by a combinationof both cytokines (4). We observed no defect in Th1 differentiationof IRAK-deficient cells mediated by IL-12, confirming thatIL-18 signaling does not play an essential role in Th1 development.IL-18–induced IFN- ${gamma}$ expression in IRAK-deficient Th1 cellsis significantly decreased, although NF- ${kappa}$ B activation is onlypartially impaired. Increase in serum IFN- ${gamma}$ levels as a result of a Th1 response to P. acnes and LPS treatment, or an NK response in the early phase of MCMV infection, was also reducedsignificantly in IRAK-deficient mice. The results suggest thatoptimal gene induction by IL-18 requires proper activationof multiple signaling pathways including NF- ${kappa}$ B and JNK. Dramaticdecrease in IFN- ${gamma}$ production in IRAK-deficient cells may haveresulted from the impairment in JNK activation even though NF- ${kappa}$ Bactivity was not severely affected. We also observed similarphenomena in our previous studies; IL-6 induction in IRAK-deficient fibroblasts in response to IL-1 treatment was significantly reduced due to defects in JNK/p38 activation despite minimalimpacts on NF- ${kappa}$ B activation (25). The involvement of both JNKand NF- ${kappa}$ B pathways may imply that optimal gene expression dependson the binding of multiple transcription factors including NF- ${kappa}$ Band AP-1 onto the promoter regions of the target genes. It isalso possible that the transactivation potential of NF- ${kappa}$ B ismodulated by the kinase activity of JNK and the other MAP-relatedkinase p38, as suggested in studies of TNF-induced IL-6 geneexpression (43).

IL-18 and IL-12 share many biological properties, although different signaling pathways are used by the two cytokines. Transcription factor STAT4 is activated by IL-12 whereas NF- ${kappa}$ Band AP-1 are activated by IL-18. The binding sites of thesetranscription factors within the IFN- ${gamma}$ promoter region havebeen identified (44). IL-18 alone can directly induce IFN- ${gamma}$ promoter activity via AP-1, whereas IL-12– mediated inductionof the promoter activity requires both AP-1 and STAT4 (44).Synergistic expression of IFN- ${gamma}$ by IL-18 and IL-12 probablyresults from the interplay of multiple transcription factorsin differential regulation of IFN- ${gamma}$ promoter activity. A strongsynergistic effect in IFN- ${gamma}$ induction and cell proliferationwas observed in IRAK-deficient Th1 cells when treated with combinationof IL-12 and IL-18. The results suggest that minimal activationof NF- ${kappa}$ B and JNK by IL-18 in IRAK-deficient cells is sufficientto function synergistically with IL-12 to achieve a significant synergistic response.

MCMV Infection in IRAK-deficient Mice.
MCMV infection in mice results in a strong NK response in theearly phase of infection before the onset of T and B cell responses(34). Induction of NK cell IFN- ${gamma}$ production and cytotoxicity peaks on day 2–5 of infection (34, 45). IFN- ${gamma}$ production by NK cells is the major defense mechanism in controlling MCMV replication (34). It has been well characterized that in MCMV infection IL-12 plays a major role in NK cell IFN- ${gamma}$ production, whereas induction of NK cytotoxicity is regulatedby IFN- ${alpha}$ /β (35, 46). Although IL-18 is known to be involvedin NK cell function, the role of IL-18 in NK responses duringMCMV infection has not been investigated. We have undertakenthis study to understand the importance of IRAK in IL-18–mediatedresponses in a viral infection. MCMV-infected IRAK-deficientmice have a normal induction of IL-18 expression but exhibiteda significant decrease in IFN- ${gamma}$ induction and in serum IFN- ${gamma}$ . The results in this study suggest that IL-18 plays a distinct role in IFN- ${gamma}$ production during the NK response to MCMV infectionand that its function cannot be overcome completely by IL-12or other mechanisms. However, we cannot rule out the possibilitythat IRAK may also play a role in viral infections via itsinvolvement in other related receptors in addition to the IL-18receptor. Although we have demonstrated a defect in IL-18–inducedNK cytotoxicity in IRAK-deficient mice, MCMV infection or poly(I):poly(C) injection triggers a normal NK cytotoxicity in these mice. Our results suggest that the role of IL-18 in NK cytotoxicitycan be compensated by IFN- ${alpha}$ /β or other mechanisms duringMCMV infection. Studies are underway in our laboratory to understandthe mechanisms of MCMV-induced immune responses in IRAK-deficientmice.

	Acknowledgments

We thank Julie Culver and Michelle Courtney for their excellenttechnical assistance, and Lars Karlsson for critical reviewof the manuscript.

This work was supported in part by grants from the NationalInstitutes of Health to P. Ghazal (CA66167 and AI30627). P.Ghazal is a Scholar of the Leukemia Society of America. A. Angulois a Fellow from the University of California UniversitywideAIDS research program.

Submitted: 19 November 1998
Revised: 3 February 1999

References

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