Role of SODD in Regulation of Tumor Necrosis Factor Responses

Signaling from tumor necrosis factor receptor type 1 (TNFR1)can elicit potent inflammatory and cytotoxic responses thatneed to be properly regulated. It was suggested that the silencerof death domains (SODD) protein constitutively associates intracellularlywith TNFR1 and inhibits the recruitment of cytoplasmic signalingproteins to TNFR1 to prevent spontaneous aggregation of thecytoplasmic death domains of TNFR1 molecules that are juxtaposedin the absence of ligand stimulation. In this study, we demonstratethat mice lacking SODD produce larger amounts of cytokines inresponse to in vivo TNF challenge. SODD-deficient macrophagesand embryonic fibroblasts also show altered responses to TNF.TNF-induced activation of NF- ${kappa}$ B is accelerated in SODD-deficientcells, but TNF-induced c-Jun N-terminal kinase activity is slightlyrepressed. Interestingly, the apoptotic arm of TNF signalingis not hyperresponsive in the SODD-deficient cells. Together,these results suggest that SODD is critical for the regulationof TNF signaling.

INTRODUCTION

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Introduction

Studies of tumor necrosis factor receptor (TNFR) superfamilysignaling bear important physiological implications, as thesereceptors play critical roles in the processes of programmedcell death, immune responses, organ development, and metabolism(3, 13). The initial theory of how TNFRs are triggered proposedthat unliganded monomeric receptors are trimerized upon bindingto their respective ligands, which also function as trimers(8, 19, 25). TNFR type 1 (TNFR1) belongs to a subset of theTNFR superfamily that possesses death domains in the cytoplasmicregions of the receptors (23). The death domain of TNFR1 iscrucial for recruiting signaling proteins, transducing downstreamsignaling pathways leading to both cell death and NF- ${kappa}$ B activation.It was thought that ligand-dependent trimerization of TNFR1brings together cytoplasmic death domains, which then initiatedownstream signaling pathways by recruiting the TNFR-associateddeath domain protein (TRADD) (7).

One potential danger of such a receptor-triggering mechanismis that TNFR1 molecules might oligomerize accidentally if theyare in close proximity, leading to inappropriate intracellularsignaling without ligand stimulation. Indeed, when TNFR1 isartificially overexpressed, the receptor spontaneously self-associatesand signals independently of ligand binding (7, 27). In a physiologicalsetting, unwarranted TNFR1 signaling must also be prevented.Discovery of the protein silencer of death domain (SODD) ledto the proposal that SODD directly binds to TNFR1 and inhibitsthe recruitment of TRADD to the death domain of TNFR1 (9). UponTNF binding to TNFR1, SODD has been shown to be transientlyreleased from the TNFR1 receptor complex, thus permitting signaltransduction from TNFR1. After $~$ 10 min of TNF stimulation, SODDis recruited back to the receptor complex, resulting in a dampeningof the intensity of TNFR1 signal transduction (9).

Recently, the theory of ligand-induced trimerization of TNFRshas been challenged by studies showing that receptor trimerscan be assembled independently of ligands. A pre-ligand-bindingassembly domain located in the extracellular domain of the receptoris required for such ligand-independent trimer formation and,more importantly, for efficient signaling upon ligand stimulation(2, 18). This new model implies that certain conformationalchanges occur in receptors as a result of ligand binding. Inthe context of the new model, the in vivo significance of SODDin TNFR1 signaling warrants further investigation.

In addition to TNFR1, SODD can also associate with the cytoplasmicregion of death receptor 3 (DR3) (9). However, SODD does notinteract with other death receptors, such as Fas, DR4, and DR5,or with intracellular signaling proteins, such as TRADD, theFas-associated death domain (FADD) protein, or receptor-interactingprotein. SODD has a characteristic protein binding domain calledthe BAG domain that is required for binding to TNFR1 and theATPase domain of heat shock protein 70 (Hsp70). In vitro, SODDis able to disassemble aggregated TNFR1 in the presence of ATP,suggesting that SODD may function to modulate conformationalchanges in TNFR1 in a manner analogous to the function of thenucleotide exchange factor BAG-1 in the ATPase cycle of Hsp70(15).

To investigate the physiological function of SODD in TNFR1 signalingin vivo, we generated SODD^-/- null mutant mice. SODD is dispensablefor normal embryogenesis and organ development. However, whenchallenged with TNF, SODD^-/- mice displayed increased cytokineproduction compared to their wild-type counterparts. Our studydemonstrates the importance of SODD in the regulation of theTNFR1 signaling pathway.

MATERIALS AND METHODS

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Materials and Methods

Generation of SODD^-/- mice. A genomic clone containing the mouse SODD gene was isolatedfrom the screening of a 129/Ola mouse genomic DNA phage librarywith a full-length cDNA probe. The targeting vector was constructedby replacing a SODD coding exon (corresponding to cDNA nucleotides274 to 378) with the neomycin resistance cassette in the reverseorientation. The targeting vector was linearized with SacI andelectroporated into E14K ES cells (Bio-Rad Gene Pulser; 0.34kV; 250 µF). After G418 selection (200 µg/ml; GIBCO-BRL),homologous recombinants were identified by PCR and confirmedby Southern blot analysis with an external probe, as depictedin Fig. 1A. Four clones heterozygous for the targeted mutationwere injected into 3.5-day C57BL/6 blastocysts, which were subsequentlytransferred into pseudopregnant foster mothers. The chimericmice were crossed with C57BL/6 mice to produce heterozygousSODD^+/- mice. The heterozygotes were intercrossed to generatehomozygous SODD^-/- mice. The genotypes of the mutant mice weredetermined by PCR and confirmed by Southern blot analysis ofgenomic DNA from tail biopsy samples. As shown in Fig. 1A, primersa and b were used to detect the wild-type allele, and primersb and c were used to detect the mutant allele. The sequencesof these primers were as follows: primer a, 5'-GCT CCA TAC CCAGGC TCC TAC T-3'; primer b, 5'-CCT TTA AGA GCA GCT GGC CAA CACAAA C-3'; primer c, 5'-AAG CGC ATG CTC CAG ACT GCC TTG GGA A-3'.

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FIG. 1. Generation of SODD-null mutant. (A) Targeting vector to create SODD mutation. The genomic structures of the SODD gene and the exon that was targeted are indicated. Probe A indicates the position of the diagnostic probe in the endogenous flanking region outside of the targeting vector. a, b, and c, positions of primers that were utilized for genotyping. Wt., wild-type; Mt., mutant. (B) Southern blot analysis of mouse tail DNA. The genomic DNA was digested with XbaI, fractionated on an agarose gel, blotted, and probed with probe A. +/+, wild type; +/-, heterozygous mutant; -/-, homozygous mutant. (C) PCR genotyping of mouse tails. Primers a, b, and c were utilized in the same PCRs that yielded products of wild-type (top) and mutant (bottom) alleles. (D) Western blot analysis of proteins from primary EF. Total cellular proteins were fractionated on an SDS-PAGE gel, blotted, and probed with a specific antibody against SODD. The blot was then stripped and reprobed with actin for a loading control.

Western blot analyses. Total cell lysates were fractionated by gel electrophoresison 10% Tris-glycine polyacrylamide gels (Novex) and transferredto polyvinylidene difluoride membranes (Millipore). The blotswere subsequently incubated with anti-SODD (N-19; Santa CruzBiotechnology), anti-I ${kappa}$ B ${alpha}$ (Cell Signaling), anti-anti-phospho-c-Jun(KM-1; Santa Cruz Biotechnology), and anti-actin (Sigma) antibodies.Immunoblot analyses were performed with horseradish peroxidase-conjugatedgoat anti-rabbit or goat anti-mouse (Amersham-Pharmacia) secondaryantibodies, and proteins were visualized with the ECL Plus enhancedchemiluminescence system (Amersham-Pharmacia) according to themanufacturer's instructions.

NO and cytokine measurements. Resident macrophages were isolated from peritoneal lavage fluid,counted, plated (2.5 x 10⁴ cells/well), and incubated with variousconcentrations of recombinant mouse TNF- ${alpha}$ plus 100 U of recombinantmouse gamma interferon (IFN- ${gamma}$ ) (R&D Systems)/ml for 24 h.In experiments where embryonic fibroblasts (EF) were used, 10⁵cells were plated in 24-well plates for TNF treatment for 24h. The supernatants were assayed for nitrite, the stable endproduct of NO, using the Griess Reagent System (Promega). Theinterleukin 1 (IL-1) and IL-6 levels in sera or culture supernatantswere measured using enzyme-linked immunosorbent assay kits (R&D)following the manufacturer's instructions.

Flow cytometric analyses. Single-cell suspensions were prepared from thymus, spleen, lymphnodes, and bone marrow. For each cytometric analysis, 5 x 10⁵cells were used. All antibodies (including those detecting CD4,CD8, CD25, CD44, and CD3) were purchased from BD PharMingen.After the cells were stained, fluorescent signals on the cellsurfaces were analyzed with a FACSCalibur flow cytometer (BectonDickinson) and CellQuest software.

Thymocyte and EF death asssay. Freshly isolated thymocytes were cultured in RPMI supplementedwith 10% fetal calf serum at a concentration of 10⁶/ml in 48-wellplates. The thymocytes were treated with mouse TNF- ${alpha}$ (10 ng/ml),cycloheximide (10 µg/ml; Sigma), Fas ligand (10 µg/ml;FasL-CD8 fusion protein), or z-VAD (50 µM; Sigma). After20 h of incubation at 37°C, the cells were harvested andstained with fluorescein isothiocyanate-CD8 ${alpha}$ , phycoerythrin-CD4,and 7-AAD (1 µg/ml; Sigma) and analyzed by flow cytometryas previously described. Viable (7-AAD-negative), double-positive(CD4⁺ CD8⁺) cells were identified. In the primary EF death assay,viable cells were determined by trypan blue exclusion.

RESULTS

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Results

Generation of SODD-deficient mice. The SODD gene was disrupted in murine embryonic stem (ES) cellsby homologous recombination using a targeting vector, as shownin Fig. 1A, which was designed to replace a SODD exon (exon2) with a PGK-neo cassette. Southern blot analysis using a flankingprobe (probe A [Fig. 1A]) on XbaI-digested genomic DNAs of EScell clones demonstrated a 3.5-kb fragment for the wild-typeallele and a 4.5-kb fragment for the targeted allele (Fig. 1B).Heterozygous ES cell lines containing a mutated SODD allelewere injected into C57BL/6 blastocysts, and chimeras with germline transmission were used to generate SODD^+/- mice by matingwith C57BL/6 mice. Heterozygous SODD^+/- mice were healthy andfertile, and from heterozygous intercrosses, homozygous SODD^-/-mice were born at the expected Mendelian ratio. Southern blotanalyses of genomic DNAs from wild-type and heterozygous andhomozygous mutant mice are shown in Fig. 1C. To determine whetherthis was a null mutation, primary EF were derived from wild-typeand SODD^-/- mice, and SODD protein expression was analyzed byWestern blotting using a specific antibody. As shown in Fig.1D, no protein could be detected in SODD^-/- primary EF. SODD^-/-mice appeared healthy and showed no obvious abnormalities macroscopicallyor microscopically in the brain, heart, lung, liver, kidney,and skin (data not shown).

Increased responsiveness of SODD^-/- mice and cells to TNF stimulation. Since SODD has been implicated in the regulation of TNF signaling,we first analyzed the in vivo response of SODD^-/- mice to TNFchallenge. Murine TNF was injected into the peritoneal cavitiesof wild-type and SODD-deficient animals, and then the levelsof IL-6 and IL-1ß in serum were measured by enzyme-linkedimmunosorbent assay. Wild-type mice were the littermate controlsfor mutant mice. Although the levels of IL-1ß 4 hfollowing injection were variable, overall we found that thecytokine responses from SODD^-/- mice were abnormally elevatedboth 2 and 4 h after TNF injection (Fig. 2A). In contrast, IL-1ßinjection into wild-type and SODD-deficient mice induced similarlevels of cytokine elevation (Fig. 2B). In addition, no constitutivelevels of IL-6, IL-1, or TNF could be detected in sera fromunstimulated wild-type or SODD-deficient mice (Fig. 2A and Band data not shown).

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FIG. 2. Increased TNF responses in SODD-deficient mice and cells. (A) In vivo cytokine response to TNF challenge. Concentrations of IL-6 or IL-1 in serum were measured for four wild-type and four SODD^-/- mice 0, 2, or 4 h after intraperitoneal TNF injection (10 µg/mouse). (B) In vivo cytokine response to IL-1 injection. Levels of IL-6 in serum were determined for three wild-type and three SODD^-/- mice 0, 2, or 4 h after intraperitoneal IL-1 injection (10 µg/mouse). (C) Production of NO from macrophages in response to TNF. Peritoneal resident macrophages isolated from wild-type and SODD^-/- mice were stimulated with 100 U of IFN- ${gamma}$ /ml plus increasing concentrations of TNF, and NO production was measured after 24 h. (D) Cytokine responses of primary EF to TNF stimulation. Wild-type and SODD^-/- primary EF were stimulated with 100 U of IFN- ${gamma}$ /ml plus various concentrations of TNF for 24 h, and IL-6 production in the culture supernatant was measured. (E) Cytokine response of primary EFs to IL-1 stimulation in comparison to TNF treatment. Wild-type and mutant EFs were stimulated with 10 ng of IL-1 or TNF/ml for 24 h, and IL-6 production was measured. Measurements of NO and cytokines were performed in triplicate for each condition. The error bars indicate standard errors.

To determine whether this defect in the TNF response could bedetected at the cellular level, we first examined the responsesof wild-type and SODD^-/- macrophages to TNF. Wild-type and mutantmacrophages were derived from mice of the same litter. Whenperitoneal resident or bone marrow-derived macrophages fromwild-type and mutant animals were stimulated with TNF plus 100U of IFN- ${gamma}$ /ml, we observed a mild increase in nitric oxide (NO)production by SODD-deficient macrophages compared to that bywild-type macrophages (Fig. 2C and data not shown). We alsoexamined the TNF response of SODD^-/- primary EF. Again, wild-typeand mutant EF were derived from embryos of the same litter.Although EF cells do not produce detectable amounts of NO afterTNF stimulation (data not shown), they do produce IL-6 in responseto TNF. When we assayed IL-6 production, we found that SODD^-/-primary EF produced an increased amount of IL-6 compared withwild-type EFs in response to TNF stimulation (Fig. 2D and E).In contrast, levels of IL-6 production induced by IL-1 in wild-typeand SODD^-/- cells were comparable (Fig. 2E). These data suggestthat SODD-deficient animals and cells respond to TNF in a deregulatedmanner.

Since deregulated TNF signaling has been shown to result inreduced lymphoid compartments in various mutant mice (10, 16,28), we next examined the development and cellularity of lymphocytesin SODD-deficient mice. Interestingly, in SODD^-/- mice, totalthymocyte numbers were significantly reduced compared to thosein wild-type mice (Fig. 3A). However, the distribution of thymocytesubpopulations, including CD4^- CD8^- (double-negative), CD4⁺CD8⁺ (double-positive), and CD4⁺ or CD8⁺ single-positive cellpopulations, was not altered in SODD^-/- mice compared to wild-typemice (Fig. 3C). Also, in the population of CD3^- CD4^- CD8^- triple-negativethymocytes, the proportions of thymocytes in the TN1 to TN4subpopulations, as delineated by CD25 and CD44 expression, inboth wild-type and SODD^-/- mice were similar (Fig. 3C). In termsof the peripheral lymphocyte compartment, we observed a reductionin total splenocyte numbers in SODD^-/- mice, although therewas variability among individuals (Fig. 3B). Despite this reductionin cellularity, the proportions of CD4⁺ versus CD8⁺ T cells(Fig. 3D) and of T cells versus B cells (data not shown) wereunaltered in mice lacking SODD. The activation status of T cellswas evaluated by expression of the early activation marker CD25,and we found that SODD^-/- T cells did not exhibit any alterationsin activation status compared to wild-type T cells (Fig. 3D).

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FIG. 3. Analysis of the lymphoid compartment in SODD^-/- mice. (A) Total thymocyte numbers in wild-type (WT) and SODD^-/- mice. Thymocyte cell counts were taken from four wild-type and four mutant mice at 6 to 8 weeks of age, and the mean and standard errors are shown. (B) Splenocyte cell counts from wild-type and SODD^-/- mice. Total splenocytes were counted for four wild-type and four mutant mice, and the mean and standard errors are shown. (C) Thymocyte surface marker expression levels analyzed by flow cytometry. Total thymocytes isolated from wild-type and SODD^-/- mice were analyzed for the expression of CD4 and CD8 (top). Cells that were double negative for CD4 and CD8 were gated and analyzed for the expression of CD25 and CD44 (bottom). Numbers indicate percentages of total or gated cells. (D) Profiles of surface marker expression in splenocytes. Total splenocytes from wild-type and mutant mice were stained for the expression of CD3, CD25, CD4, and CD8.

Enhanced TNF-induced NF- ${kappa}$ B activation but unaltered cell death in SODD-deficient cells. To investigate whether SODD deficiency renders cells more sensitiveto TNF-induced apoptosis, we examined SODD^-/- thymocytes andEF along with their wild-type controls. As shown in Fig. 4,SODD-deficient thymocytes and EF showed viability similar tothat of their wild-type counterparts in response to TNF stimulation.These results indicated that while SODD deficiency results inincreased cytokine production in response to TNF signaling,the TNF-induced cell death pathway either is not subjected toregulation by SODD or is counteracted by other mechanisms inthe absence of SODD.

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FIG. 4. Normal TNF-induced cell death in SODD-deficient cells. (A) Thymocyte death induced by TNF and Fas ligand (FasL). Wild-type (WT) and SODD^-/- thymocytes were stimulated with various reagents as indicated, including two death receptor ligands, TNF, and FasL, or were untreated. After 24 h, the cells were stained with CD4, CD8, and 7-AAD. The percentages (plus standard errors) of viable CD4⁺ CD8⁺ (7-AAD-negative) cells are shown. CHX, cycloheximide; zVAD, caspase inhibitor. (B) Primary EF cell death induced by TNF plus cycloheximide. Wild-type and SODD^-/- primary EF were treated with TNF in the absence or presence of cycloheximide (1 or 10 µg/ml) for 24 h. The percentages (plus standard errors) of viable cells capable of excluding trypan blue are shown.

Through TNFR1, TNF is capable of triggering the activation ofNF- ${kappa}$ B in addition to a cell death pathway. NF- ${kappa}$ B is the transcriptionfactor that has been shown to play an important role in cellsurvival, as well as in the production inflammatory cytokines.We therefore examined the effect of SODD deficiency on TNF-inducedNF- ${kappa}$ B activation in EF cells. We first performed gel mobilityshift assays to evaluate the NF- ${kappa}$ B activities by their abilitiesto bind to DNA but found no significant difference between wild-typeand SODD^-/- EF (data not shown). We then specifically examinedan upstream event in the activation of NF- ${kappa}$ B, that is, the degradationof I ${kappa}$ B ${alpha}$ , which allows nuclear translocation of NF- ${kappa}$ B. As shownin Fig. 5A and B, the degradation of I ${kappa}$ B ${alpha}$ appeared to be slightlyenhanced in SODD^-/- EF cells compared to that in wild-type cells.This was particularly evident at the early time points (Fig.5B). This phenomenon appeared to be specific to TNF stimulation,as IL-1 treatment triggered similar levels of I ${kappa}$ B ${alpha}$ degradationin wild-type and SODD-deficient EF (Fig. 5A).

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FIG. 5. Effect of SODD deficiency on TNF-mediated downstream signal transduction. (A) Time course of I ${kappa}$ B degradation in response to TNF or IL-1 stimulation. Wild-type (WT) and SODD^-/- primary EF were stimulated with TNF or IL-1 (10 ng/ml), and total cell lysates were harvested at various time points as indicated and analyzed for the expression of total I ${kappa}$ B ${alpha}$ protein and actin by Western blot analysis. (B) Early time courses of I ${kappa}$ B degradation upon stimulation with various concentrations of TNF. Wild-type and SODD^-/- cells were stimulated with increasing concentrations of TNF, and the extent and kinetics of I ${kappa}$ B ${alpha}$ protein degradation were determined by Western blot analysis. (C) mRNA induction of A20 and I ${kappa}$ B ${alpha}$ genes after TNF stimulation. Total RNAs from wild-type or SODD^-/- primary EF were collected at the indicated time points after TNF stimulation, and Northern blot analysis was performed to determine the kinetics of A20 gene expression. The same blot was stripped and reprobed with I ${kappa}$ B ${alpha}$ and then GAPDH (glyceraldehyde-3-phosphate dehydrogenase) cDNA. m, marker for RNA size standards on the gel. (D) Kinetics of JNK activation induced by TNF or IL-1. Activation of the JNK pathway was determined by the level of phosphorylated c-Jun in TNF- or IL-1-stimulated wild-type and SODD^-/- primary EF.

The level of I ${kappa}$ B ${alpha}$ expression at the later time points, which reflecteda dynamic balance between the ongoing I ${kappa}$ B ${alpha}$ degradation that precedesNF- ${kappa}$ B activation and new I ${kappa}$ B ${alpha}$ gene transcription that is dependenton NF- ${kappa}$ B activity, was also slightly reduced in SODD-deficientcells compared to that in wild-type cells (Fig. 5A). To furtherinvestigate this defect, we examined the kinetics of inducedtranscription of two NF- ${kappa}$ B-dependent genes, I ${kappa}$ B ${alpha}$ and A20, in SODD-deficientcells. While no difference could be observed in I ${kappa}$ B ${alpha}$ expressionin wild-type and SODD^-/- EF at various time points, a mild increaseof A20 mRNA-induced expression could be detected in SODD^-/-cells 0.5 and 1 h after TNF stimulation (Fig. 5C).

We noted that the data in Fig. 2C showing increased IL-6 productionby SODD-deficient cells indicated that the same level of IL-6induction by TNF in wild-type cells could be achieved by 1/3to 1/10 of the TNF concentration in SODD^-/- cells. To examinewhether this phenomenon is correlated with differences in NF- ${kappa}$ Bactivation in SODD-deficient versus wild-type cells, we measuredI ${kappa}$ B degradation in wild-type and SODD^-/- EF using serial concentrationsof TNF. As shown in Fig. 5B, the extent of I ${kappa}$ B degradation wasindeed dependent on the concentration of TNF, and SODD^-/- cellsrequired lower doses of TNF to induce levels of I ${kappa}$ B degradationsimilar to those observed in wild-type cells.

TNF also activates stress kinase pathways, such as JNK and p38mitogen-activated kinase (MAPK), which play roles in cell deathand the regulation of cytokine production (25). We examinedactivation of these stress kinases in SODD^-/- EF in responseto TNF and found that they were not enhanced. In fact, whilethe p38 MAPK pathway was induced normally in the mutant cells(data not shown), activation of the JNK pathway, by measuringthe level of phospho-c-Jun, was slightly decreased in cellslacking SODD compared to that in wild-type cells (Fig. 5D).However, c-Jun kinase activities as measured by an in vitrokinase assay appeared comparable in SODD-deficient and wild-typecells (data not shown). Taken together, our results suggestedthat SODD deficiency causes the enhancement of cytokine productionin response to TNF and an alteration of the complicated TNF-inducedsignaling cascades, including the enhanced NF- ${kappa}$ B signaling pathwayand slightly repressed JNK activation.

DISCUSSION

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Discussion

The complexity and importance of proper TNF signal regulationcan be illustrated by the demonstrated existence of multipleinhibitory feedback mechanisms. For example, I ${kappa}$ B ${alpha}$ and A20 areboth induced by TNF signals and function to shut down furthersignal transduction by sequestering NF- ${kappa}$ B (12) and impingingon the receptor signaling complex (5, 6, 20), respectively.The importance of these molecules in inhibiting TNF signalswas further exhibited in the knockout studies (1, 11). Interestingly,TRAF2 and TRAF1 were implicated in the transduction of TNF signalsby their recruitment to both TNFR1 and TNFR2 receptor complexes(17, 21). However, gene-targeting studies suggested that TRAF2and TRAF1 also play roles in shutting down TNF signals (24,28).

In this study, we examined the physiological function of SODD,a potential signal regulator at the very proximal end of TNFR1complex assembly. We showed that SODD deficiency results ina mild enhancement of NF- ${kappa}$ B activation and cytokine production,but not JNK activation or cell death. However, TNF signalingis not wildly deregulated in the absence of SODD. Elevated expressionof A20 plus the presence of I ${kappa}$ B proteins and TRAF2 probably participatein keeping TNFR1 signals largely in check in cells lacking SODD.Nonetheless, our results demonstrated that SODD is requiredfor optimal TNF signal regulation and that NF- ${kappa}$ B activation,particularly degradation of I ${kappa}$ B, is the downstream pathway thatis most susceptible to a defect in negative regulation of TNF-mediatedevents.

There are two major possibilities for the way in which a negativeregulator may control TNF signals. It may function as a typeof gatekeeper for a TNF receptor(s), and a deficiency of suchmolecules would result in a lower threshold being required forsignal transduction to occur. Alternatively, the negative regulatormay shut down TNF signals after the initiation of downstreampathways. Our results seem to support a role for SODD as oneof the gatekeepers for the initiation of TNFR1 signaling, andthe loss of SODD lowers the amount of TNF required to triggera certain signaling intensity (Fig. 2C and 5B). This distinguishesSODD from other major negative regulators, such as the A20 andI ${kappa}$ B proteins, which function primarily as feedback inhibitorsthat turn off signals after they have been initiated.

Although we favor a mechanism where there is a direct relationshipbetween the increase in cytokine production and the elevatedNF- ${kappa}$ B in TNF-stimulated SODD^-/- cells, we cannot rule out thecontribution of alterations in other signaling pathways, suchas the JNK pathway, to the abnormal cytokine production. Ithas been shown that in cells in which NF- ${kappa}$ B is repressed or deficient,JNK activity is increased, and this increase mediates an enhancementin cell death (4, 22). Further studies of the role of the JNKpathway alone and the reciprocal control between NF- ${kappa}$ B and JNKpathways in TNF-induced cytokine production will be requiredto address this issue.

SODD was initially proposed to prevent TNFR1 triggering in theabsence of ligand stimulation. Although there was no strongevidence from our results to support this hypothesis, we haveoccasionally observed that SODD^-/- macrophages and EF cellsproduced inflammatory cytokines (compared to wild-type cells)in the absence of TNF stimulation. Intriguingly, these SODD-deficientcells displayed a reduced cytokine response to TNF stimulation.The mutant cells may have been preactivated somehow and becamerefractory to TNF-induced responses. It is also possible thatrepressed JNK activation in SODD^-/- cells plays a role in regulatingcytokine production in this situation.

The phenotype of reduced thymocyte cellularity was consistentlyobserved in SODD^-/- mice, but it is not easily explained bythe other phenotypes of enhanced cytokine production or NF- ${kappa}$ Bactivation induced by TNF. One possible explanation is thatthe deficiency of SODD may also enhance the signaling of DR3,which has been shown to play a role in thymocyte negative selection(26). Intriguingly, TL1A, a recently identified DR3 and decoyreceptor 3 (DcR3) ligand, has been implicated in T-cell costimulationand in the killing of certain tumor cells, but not primary Tcells (14). Future studies investigating the physiological rolesof TL1A and DR3 in regulating thymocyte cellularity and theinvolvement of SODD in this signaling context may clarify whetherSODD affects thymocytes through a mechanism involving DR3.

ACKNOWLEDGMENTS

We thank D. Goeddel for helpful discussions, L. T. Nguyen forcritical review of the manuscript, and C. Tsai for technicalassistance.

This work was supported by the National Cancer Institute ofCanada with funds from the Canadian Cancer Society and by anoperating grant from the Canadian Institutes of Health Research.

FOOTNOTES

* Corresponding author. Mailing address: 620 University Ave. No. 706, Toronto, Ontario, Canada M5G 2C1. Phone: (416) 204-2232. Fax: (416) 204-2278. E-mail: wyeh{at}uhnres.utoronto.ca.

REFERENCES

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