The Protein Kinase C-Responsive Inhibitory Domain of CARD11 Functions in NF-{kappa}B Activation To Regulate the Association of Multiple Signaling Cofactors That Differentially Depend on Bcl10 and MALT1 for Association

The activation of NF- ${kappa}$ B by T-cell receptor (TCR) signaling iscritical for T-cell activation during the adaptive immune response.CARD11 is a multidomain adapter that is required for TCR signalingto the I ${kappa}$ B kinase (IKK) complex. During TCR signaling, the regionin CARD11 between the coiled-coil and PDZ domains is phosphorylatedby protein kinase C ${theta}$ (PKC ${theta}$ ) in a required step in NF- ${kappa}$ B activation.In this report, we demonstrate that this region functions asan inhibitory domain (ID) that controls the association of CARD11with multiple signaling cofactors, including Bcl10, TRAF6, TAK1,IKK ${gamma}$ , and caspase-8, through an interaction that requires boththe caspase recruitment domain (CARD) and the coiled-coil domain.Consistent with the ID-mediated control of their association,we demonstrate that TRAF6 and caspase-8 associate with CARD11in T cells in a signal-inducible manner. Using an RNA interferencerescue assay, we demonstrate that the CARD, linker 1, coiled-coil,linker 3, SH3, linker 4, and GUK domains are each required forTCR signaling to NF- ${kappa}$ B downstream of ID neutralization. Requirementsfor the CARD, linker 1, and coiled-coil domains in signalingare consistent with their roles in the association of CARD11with Bcl10, TRAF6, TAK1, caspase-8, and IKK ${gamma}$ . Using Bcl10- andMALT1-deficient cells, we show that CARD11 can recruit signalingcofactors independently of one another in a signal-induciblemanner.

INTRODUCTION

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INTRODUCTION

The NF- ${kappa}$ B family of transcription factors plays important pleiotropicroles in the regulation of cellular activation, proliferation,and survival. The precise regulation of NF- ${kappa}$ B activity is criticalfor several biological processes including innate and adaptiveimmunity (22, 54), learning and memory (34), epidermal developmentand homeostasis (2), bone formation and metabolism (65), andembryonic development (19). In most normal cells, NF- ${kappa}$ B is inactivebut is poised for rapid posttranslational activation by a diversearray of stimuli such as bacterial and viral products, proinflammatorycytokines, antigens recognized by lymphocytes, DNA-damagingagents, and UV irradiation.

A remarkable aspect of NF- ${kappa}$ B regulation is that each of thesestimuli can activate the I ${kappa}$ B kinase complex (IKK complex) (50).An emerging theme is that a ligand-receptor pair that may bespecialized to a particular biological context will signal tothe IKK complex through adapter molecules that can receive stimulus-specificmolecular signals and transmit that information to widely expressedsignaling cofactors that are of general use. The IKK complexactivates NF- ${kappa}$ B by canonical and noncanonical pathways (50),both of which link IKK kinase activity to the phosphorylationand degradative processing of inhibitory proteins that keepNF- ${kappa}$ B inactive in the unstimulated state.

NF- ${kappa}$ B is one of the key transcription factors that are inducedwhen a T lymphocyte is activated by antigenic stimulation inthe adaptive immune response (51). Following the engagementof antigen by the T-cell receptor (TCR) complex and concomitanttriggering of costimulatory receptors like CD28, a cascade ofsignaling results in the activation of the IKK complex. A cadreof TCR-proximal molecules transduces signals from the TCR complexto elicit activation of protein kinase C ${theta}$ (PKC ${theta}$ ), a kinase thatis required in this pathway (60) and that is recruited to thecentral portion of the supramolecular activation cluster orimmunological synapse (36, 37). TCR-proximal molecules thatfunction between the TCR and PKC ${theta}$ and have been shown to be requiredfor NF- ${kappa}$ B activation include the adapters SLP-76 (23) and SAP(5), the tyrosine kinases Fyn (5) and ZAP-70 (23), the Vav1GTP/GDP exchange factor (9), phospholipase C ${gamma}$ 1 (11), and theserine/threonine kinases PDK1 (27) and IRAK4 (61). The requirementsfor these molecules in the pathway can be bypassed by treatingT cells with phorbol ester and calcium ionophore (phorbol myristateacetate [PMA] and ionomycin), which are thought to activatePKC ${theta}$ directly.

The role of PKC ${theta}$ in TCR-mediated NF- ${kappa}$ B activation appears to beto regulate the signaling function of CARD11 (also known asCARMA1 or BIMP3). CARD11 is a multidomain signaling scaffoldthat contains a caspase recruitment domain (CARD) in additionto coiled-coil, PDZ, Src homology 3 (SH3), and GUK domains (3,18). CARD11 is expressed in a cell-type-restricted manner (3,18). The presence of PDZ, SH3, and GUK domains is a signaturefeature of the membrane-associated guanylate kinase family ofproteins, which function in diverse organisms and tissues tolocalize and assemble clusters of signaling proteins for efficientsignaling (13). Several studies have established that CARD11is required for TCR signaling to NF- ${kappa}$ B upstream of IKK complexactivation (15, 17, 21, 25, 41, 44, 68).

During TCR signaling, CARD11 is phosphorylated on serine residues564, 577, and 657 in a region between the coiled-coil and PDZdomains (32, 55). Serine residues 564 and 657 have been shownto be substrates for PKC ${theta}$ in vitro (32, 55). It has been proposedthat the signal-induced phosphorylation of CARD11 somehow convertsthe protein into an active state that can induce and coordinatesignaling to the IKK complex. Molecules that have been implicatedin IKK activation downstream of CARD11 include the Bcl10 adaptermolecule (31, 47), the MALT1 paracaspase (7, 46, 48), the TRAF2and TRAF6 E3 ubiquitin ligases (59), the TAK1 kinase (29, 49,53, 59, 66), and caspase-8 (58), all of which are widely expressed.

Several studies have proposed mechanisms for how the IKK complexis activated in this pathway. The K63-linked ubiquitinationof IKK ${gamma}$ has been implicated in this process, mediated eitherby MALT1 (73) or TRAF6 (59) in a manner promoted by Bcl10 oligomerization.In addition, TCR-mediated IKK activation has also been shownto correlate with the TAK1-mediated phosphorylation of IKKβ(52, 59) and the TRAF6-mediated ubiquitination of MALT1 (43).The proteolytic activity of caspase-8 has also been demonstratedto be required for IKK activation in this pathway, but its relevantsubstrate has not been reported (58).

CARD11 activity during TCR signaling correlates with the relocalizationof Bcl10 and the IKK complex to the T-cell membrane, to thecentral portion of the supramolecular activation cluster, andto lipid rafts (15, 20, 32, 55). While Bcl10, MALT1, and IKK ${gamma}$ have previously been shown to associate with CARD11 during TCRsignaling (17, 56, 67, 69), the precise mechanisms by whichCARD11 interprets upstream signals from the TCR and coordinatesthe activities of cofactors in IKK activation are poorly understood.

In this study we report that the inhibitory domain (ID) thatfunctions to keep CARD11 inactive in the absence of TCR signalingtargets both the CARD and the coiled-coil domain of CARD11 andcan regulate the association of CARD11 with several signalingcofactors. We investigate which domains in CARD11 function downstreamof PKC ${theta}$ -mediated conversion of the protein to an active scaffoldingmolecule, and we ascribe recruitment functions to three N-terminaldomains in the association of Bcl10, TRAF6, TAK1, caspase-8,and IKK ${gamma}$ . Consistent with the ID-mediated control of the associationof CARD11 with TRAF6 and caspase-8, we demonstrate that signalinginduces the association of TRAF6 and caspase-8 with CARD11 inT cells. Finally, we demonstrate that the ID-regulated associationof TAK1, TRAF6, and IKK ${gamma}$ with CARD11 can occur in Bcl10-deficientand MALT1-deficient cells, indicating that CARD11 can recruitsignaling cofactors independently of one another in a signal-induciblemanner.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Generation of Jurkat T cells and HEK293T cells with stable expression of shRNA. Self-inactivating lentiviral constructs based upon the vectorFUGW (30) were constructed to express either sihCARD11-2 (44)or siMUT (44) short hairpin RNAs (shRNAs) downstream of thehuman H1 RNA promoter, and the puromycin resistance gene downstreamof the cytomegalovirus (CMV) enhancer/chicken β-actin promoterfusion as indicated in Fig. 1A. In the lentivirus encoding thesiMUT hairpin, the H1 RNA promoter and hairpin are in the oppositeorientation to the configuration depicted in Fig. 1A. To packagelentiviruses, HEK293T cells were plated at 2.5 x 10⁶ per 10-cmplate 24 h prior to calcium phosphate-mediated transfectionwith 3.75 µg of pCL-Ampho (40), 3.75 µg of pMDL/pRRE(14), 3.75 µg of RSV-Rev (14), and 3.75 µg of lentiviralconstruct encoding either no hairpin, the siCARD11-2 hairpin,or the siMUT hairpin. The medium was changed 24 h after transfection,and at 48 h after transfection viral supernatant was supplementedwith polybrene (8 µg/ml) and added to Jurkat T-cell cultures.Forty-eight hours after the addition of viral supernatant, JurkatT cells were resuspended in fresh medium containing puromycinat 0.5 µg/ml and selected for 2 weeks. Puromycin-resistantJurkat pools were maintained in medium containing 0.5 µg/mlpuromycin. Knockdown of CARD11 was assessed by Western analysisof total cell lysates using antiserum raised against murineCARD11 (gift of D. Baltimore) and antibodies to IKK ${alpha}$ (sc-7606;Santa Cruz Biotechnology).

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FIG. 1. The linker domains in CARD11 are required for regulated TCR signaling to NF- ${kappa}$ B. (A) Schematic of lentiviral constructs. Following integration, the human H1 RNA promoter drives expression of an shRNA, and the CMV enhancer/chicken β-actin promoter fusion drives expression of the puromycin resistance gene (PURO). The virus contains a flap sequence (F) for increased nuclear translocation efficiency and a Woodchuck hepatitis virus posttranscriptional regulatory element (WPRE) for enhanced expression. The sequences of the sihCARD11-2 and siMUT shRNAs are depicted. (B) Jurkat T-cell pools infected with viruses expressing no hairpin (-), the sihCARD11-2 hairpin, or the siMUT hairpin were transfected with 200 ng of pCSK-LacZ and 2,800 ng of either Ig ${kappa}$ ₂-IFN-LUC or NFAT-LUC and stimulated with anti-CD3/anti-CD28 cross-linking as indicated. The lower panels are Western blots of total cell extracts of the infected pools probed with antibodies to CARD11 or IKK ${alpha}$ . (C) Schematic of the domain structure of CARD11. The numbers indicate the amino acid position according to Pomerantz et al. (44). (D) The Jurkat T-cell pool stably expressing the sihCARD11-2 shRNA was transfected with 200 ng of pCSK-LacZ and 1,800 ng of Ig ${kappa}$ ₂-IFN-LUC in the absence or presence of 200 ng of the indicated CARD11 variant expression construct. Cells were stimulated with anti-CD3/anti-CD28 cross-linking as indicated. The bars represent the mean values of triplicate samples, and error bars indicate the standard deviation. WT, wild type; ${alpha}$ , anti.

The KD-GFP, KD-Bcl10, and KD-MALT1 HEK293T (KD, knockdown) celllines were infected with lentiviruses based on pLKO.1 (35) andexpressing shRNAs targeting the following sequences: for greenfluorescent protein (GFP), 5'-AAGGCTACGTCCAGGAGCGCA-3'; forBcl10, 5'-GTTGAATCTATTCGGCGAGAA-3'; for MALT1, 5'-CCTCACTACCAGTGGTTCAAA-3'.To package these lentiviruses, HEK293T cells were plated at9 x 10⁴ per well in a 24-well plate 24 h prior to calcium phosphate-mediatedtransfection with 50 ng of pCMV-VSVG (39), 100 ng of pMDL/pRRE,35 ng of RSV-Rev, and 200 ng of lentiviral construct. At 48h after transfection viral supernatant was supplemented withpolybrene (8 µg/ml) and added to fresh HEK293T cell cultures.Twenty-four hours after the addition of viral supernatant, HEK293Twere selected for 2 weeks in the presence of puromycin at 1µg/ml. Knockdown was assessed by Western analysis of totalcell lysates using antibodies to Bcl10 (sc-5273; Santa CruzBiotechnology) and MALT1 (1664-1; Epitomics). The KD-GFP, KD-Bcl10,and KD-MALT1 Jurkat T-cell lines were infected by the identicalpLKO.1-based lentiviruses and selected and maintained in mediumcontaining 0.5 µg/ml puromycin.

Reporter assays of HEK293T cells. HEK293T cells were grown in Dulbecco's modified Eagle's mediumsupplemented with 10% fetal bovine serum, 100 U/ml each of penicillinand streptomycin, and 2 mM glutamine in humidified 5% CO₂ at37°C. One day prior to infection, 9 x 10⁴ cells were platedin 0.5 ml of medium in each well of a 24-well plate. On theday of transfection, 376 ng of DNA was transfected by the calciumphosphate method, including 20 ng of the reporter Ig ${kappa}$ ₂-IFN-LUC(44), 6 ng of pCSK-LacZ (8), and up to 350 ng of the expressionconstruct to be tested. In each experiment, each sample wassupplemented with empty parental expression vector (pcDNA3;Invitrogen) to keep the total amount of expression vector constant.The medium was changed 20 to 24 h following transfection, and40 to 44 h following transfection cells were lysed in 100 µlof reporter lysis buffer (Promega) at room temperature. Cellswere scraped and spun at 16,000 x g at room temperature for10 min to pellet debris. Twenty microliters of lysate was usedto measure luciferase activity using a luciferase assay system(Promega) and a luminometer (Perkin Elmer TR717) integratingfor 10 s after a 2-s delay, according to the manufacturer'sinstructions. β-Galactosidase (β-Gal) activity wasdetermined using 10 µl of lysate and a chemiluminescentβ-Gal reporter gene assay (Roche) according to the manufacturer'sinstructions. Relative stimulation was calculated for each sampleby dividing the luciferase activity, normalized to β-Galactivity, by that observed in the sample containing only emptyexpression vector.

Reporter assays of Jurkat T cells. Jurkat T cells were grown in RPMI medium supplemented with 10%fetal bovine serum, 100 U/ml each of penicillin and streptomycin,2 mM glutamine, and 50 µM β-mercaptoethanol in humidified5% CO₂ at 37°C. On the day of transfection, 5 x 10⁵ cellswere plated in 2 ml in six-well plates prior to incubation withDNA-Fugene 6 (Roche) or DNA-Transit LT1 (Mirus) complexes, accordingto the manufacturers' instructions, using a total of 3 µgof DNA and 9 µl of Fugene 6 or LT1. Assays included eitherthe Ig ${kappa}$ ₂-IFN-LUC reporter for NF- ${kappa}$ B or the NFAT-LUC reporter forNFAT (Stratagene). In all assays 200 ng of pCSK-LacZ was includedand used as a transfection and extract recovery control. At40 to 44 h posttransfection, cells were resuspended in 1 mlof medium with or without 1 µg/ml each of anti-human CD3(BD Pharmingen 555329), anti-human CD28 (BD Pharmingen 555725),and anti-mouse immunoglobulin G1 (BD Pharmingen; 553440) antibodiesor 50 ng/ml PMA (Sigma) plus 1 µM ionomycin (Sigma) andincubated for 4 to 6 h. Following stimulation, cells were lysedin 150 µl of reporter lysis buffer (Promega) for 10 minat room temperature. Debris was removed as described above,and luciferase and β-Gal activities were measured using50 and 25 µl of lysate, respectively. In each experiment,each sample was supplemented with empty parental expressionvector (pcDNA3 or pEBB) to keep the total amount of expressionvector constant. Stimulation was calculated as described above.

Immunoprecipitations. HEK293T cells were transfected by the calcium phosphate methodas described above except that 1 day prior to transfection,5 x 10⁵ HEK293T cells were plated in each well of a six-wellplate, and a total of 2 µg of DNA was transfected. Themedium was changed 20 to 24 h posttransfection, and the cellswere harvested 44 to 48 h posttransfection. Cell lysates weremade in 440 µl of immunoprecipitation lysis buffer (150mM NaCl, 1 mM EDTA, 10% glycerol, 1% Igepal, 50 mM HEPES, pH7.9, and a protease inhibitor cocktail[Sigma P8340]). Debriswas removed by centrifugation at 16,000 x g at 4°C for 10min. The supernatant was precleared twice with a 7-µlbed volume of protein G-Sepharose 4 Fast Flow (GE Healthcare)for 1 h at 4°C with rotation. Ten percent of the preclearedlysate was saved for analysis by Western blotting, and the restwas incubated with 1 µg of anti-FLAG antibody (Sigma F7425)for 90 to 120 min at 4°C with rotation. A 7-µl bedvolume of protein G-Sepharose that had been blocked with 1%insulin (Sigma I9278) was added and incubated for 60 to 90 minat 4°C with rotation. The resulting immunocomplex was washedwith immunoprecipitation lysis buffer four times for 5 min at4°C with rotation. The samples were boiled in sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE) loadingbuffer, resolved on 10% SDS-PAGE gels, transferred to polyvinylidenedifluoride membrane, and analyzed by Western blotting usinganti-myc (sc-40; Santa Cruz Biotechnology) and anti-FLAG (M2;Eastman Kodak IB13026) antibodies.

For the experiments shown in Fig. 11 and 12, immunoprecipitationswere performed in the same manner as described above, exceptthat immunocomplexes were eluted from protein G-Sepharose beadswith two 5-min incubations at room temperature with 50 µlof 100 mM glycine, pH 3.0. Eluates were neutralized with 10µl of 3 M Tris, pH 8.8, added to SDS loading buffer, boiled,and resolved on 10% acrylamide SDS-PAGE gels. These elutionconditions were used in order to eliminate a cross-reactingprotein G band at 25 to 30 kDa. The samples were analyzed byWestern blotting using anti-myc (Santa Cruz sc-40), anti-FLAG(Eastman Kodak IB13026), anti-Bcl10 (Santa Cruz sc-5273), andanti-MALT1 (Epitomics 1664-1) antibodies.

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FIG. 11. Effect of Bcl10 and MALT1 knockdown on the association of the ${Delta}$ ID with TAK1 and TRAF6 in HEK293T cells. The KD-GFP, KD-Bcl10, and KD-MALT1 cell lines were transfected with expression vectors for the wild-type CARD11 or the ${Delta}$ ID in the absence (–) or presence (+) of expression vectors for FLAG-tagged TAK1 (A) or TRAF6 (B). Anti-FLAG immunoprecipitations were performed as described in Materials and Methods. Where indicated, transfections included 100 ng of expression vector for wild-type CARD11 and 200 ng of expression vector for either TAK1 or TRAF6. To achieve approximately equivalent expression of the ${Delta}$ ID variant in each cell line, 200 ng of ${Delta}$ ID expression vector was used in the KD-GFP line, and 400 ng was used in the KD-Bcl10 and KD-MALT1 lines. The panels show the contents of the immunoprecipitate and lysate input developed with the indicated primary antibodies. In the control lane (C), the equivalent of 5% of the lysate input from the KD-GFP sample was resolved so as to provide a positive control for the Western blot (WB) analysis of the immunoprecipitates for the presence of Bcl10 and MALT1. WT, wild type; ${alpha}$ , anti; IP, immunoprecipitation.

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FIG. 12. Effect of Bcl10 and MALT1 knockdown on the association of the ${Delta}$ ID with IKK ${gamma}$ and caspase-8 C360S in HEK293T cells. The KD-GFP, KD-Bcl10, and KD-MALT1 cell lines were transfected with expression vectors for the wild-type CARD11 or the ${Delta}$ ID in the absence (–) or presence (+) of expression vectors for FLAG-tagged IKK ${gamma}$ or caspase-8. Anti-FLAG immunoprecipitations were performed as described in Materials and Methods. In panel A, transfections included 800 ng of expression vector for IKK ${gamma}$ where indicated. To achieve approximately equivalent expression of wild-type and ${Delta}$ ID CARD11 variants in each cell line, the following amounts were used, from left to right (in ng): 100 WT, 200 ${Delta}$ ID, 100 WT, and 200 ${Delta}$ ID (for the KD-GFP cells); 200 WT, 400 ${Delta}$ ID, 100 WT, and 400 ${Delta}$ ID (for KD-Bcl10 cells); 200 WT, 400 ${Delta}$ ID, 100 WT, and 400 ${Delta}$ ID (for KD-MALT1 cells). In panel B, where indicated, transfections included 100 ng of expression vector for wild-type CARD11 and 1,000 ng of expression vector for caspase-8. To achieve approximately equivalent expression of the ${Delta}$ ID variant in each cell line, 200 ng of ${Delta}$ ID expression vector was used in the KD-GFP line, and 400 ng was used in the KD-Bcl10 and KD-MALT1 lines. The panels show the contents of the immunoprecipitate and lysate input developed with the indicated primary antibodies. In the control lane (C), the equivalent of 5% of the lysate input from the KD-GFP sample was resolved so as to provide a positive control for the Western blot (WB) analysis of the immunoprecipitates for the presence of Bcl10 and MALT1. WT, wild type; ${alpha}$ , anti; IP, immunoprecipitation.

For immunoprecipitations of endogenous CARD11, TRAF6, IKK ${alpha}$ , andcaspase-8 proteins, 1 x 10⁸ to 2 x 10⁸ Jurkat T cells per samplewere stimulated with 50 ng/ml PMA and 1 µM ionomycin for3, 5, 6, 9, 12, 15, or 30 min in a volume of 20 ml and thenplaced on ice for 10 min. Cells were then pelleted at 500 xg for 5 min and lysed on ice for 10 min in 1.5 ml of immunoprecipitationlysis buffer containing 2.5 mM sodium orthovanadate, 10 mM sodiumfluoride, and 10 mM β-glycerophosphate. Debris was pelletedby centrifugation at 16,000 x g at 4°C for 10 min. The supernatantwas precleared with a 7-µl bed volume of protein G-Sepharosefor 1 h at 4°C with rotation. Two to five percent of theprecleared lysate was saved for analysis by Western blotting,and the remaining fraction was incubated with 2 µg ofeither anti-TRAF6 (Santa Cruz sc-8409) or anti-caspase-8 (SantaCruz sc-6136) antibody overnight at 4°C with rotation orwith 2 µg of anti-IKK ${alpha}$ (Santa Cruz sc-7606) antibody for2.5 h at 4°C with rotation. A 7-µl bed volume of proteinG-Sepharose that had been blocked with 1% insulin (Sigma I9278)was added and incubated for 60 to 90 min at 4°C with rotation.The resulting immunocomplex was washed with immunoprecipitationlysis buffer four times for 5 min at 4°C with rotation.The samples were boiled in SDS-PAGE loading buffer, resolvedon 10% acrylamide SDS-PAGE gels, transferred to polyvinylidenedifluoride membrane, and analyzed by Western blotting usinganti-CARD11 (Prosci 3189) and anti-caspase-8 (Santa Cruz sc-7890),anti-TRAF6 (Santa Cruz sc-7221), or anti-IKK ${alpha}$ (Santa Cruz sc-7218)antibodies.

Glutathione-agarose precipitations. Glutathione-agarose precipitations were done as described abovefor immunoprecipitations, except that after the supernatantwas precleared with protein G-Sepharose, 10% of the lysate wassaved for analysis by Western blotting, and the rest was incubatedwith a 7-µl bed volume of glutathione-agarose (MolecularProbes) for 90 to 120 min at 4°C with rotation. The resultingcomplex was washed with immunoprecipitation lysis buffer fourtimes for 5 min with rotation at 4°C. The samples were analyzedas described above by Western blotting using anti-myc and anti-glutathioneS-transferase (GST) antibodies (sc-40 and sc-459, respectively;Santa Cruz Biotechnology).

I ${kappa}$ B ${alpha}$ degradation assays. The I ${kappa}$ B ${alpha}$ degradation assays were done as described previously(44) using anti-I ${kappa}$ B ${alpha}$ (Santa Cruz sc-371) antibody.

Expression constructs. To generate pcCARD11, a DNA fragment encoding residues 2 to1159 of murine CARD11 (44) was cloned into pcDNA3 to make anin-frame fusion to an N-terminal c-myc epitope (EQKLISEEDL).All CARD11 deletion constructs were constructed in pcDNA3 usingstandard molecular biology techniques and verified by sequencing.Each retains the N-terminal myc epitope. The ${Delta}$ CARD expressionconstruct (pc ${Delta}$ CARD) deletes residues 2 to 115. The ${Delta}$ L1 construct(pc ${Delta}$ L1) deletes residues 116 to 149, the ${Delta}$ CC construct (pc ${Delta}$ CC)deletes residues 152 to 447, the ${Delta}$ ID construct (pc ${Delta}$ ID) deletesresidues 441 to 671, the ${Delta}$ PDZ construct (pc ${Delta}$ PDZ) deletes residues669 to 752, the ${Delta}$ L3 construct (pc ${Delta}$ L3) deletes residues 759 to775, the ${Delta}$ SH3 construct (pc ${Delta}$ SH3) deletes residues 779 to 844,the ${Delta}$ L4 construct (pc ${Delta}$ L4) deletes residues 848 to 952, and the ${Delta}$ GUK construct (pc ${Delta}$ GUK) deletes residues 956 to 1159. The doubledeletion constructs pc ${Delta}$ ID ${Delta}$ CARD, pc ${Delta}$ ID ${Delta}$ L1, pc ${Delta}$ ID ${Delta}$ CC, pc ${Delta}$ ID ${Delta}$ PDZ, pc ${Delta}$ ID ${Delta}$ L3,pc ${Delta}$ ID ${Delta}$ SH3, pc ${Delta}$ ID ${Delta}$ L4, and pc ${Delta}$ ID ${Delta}$ GUK contain identical simultaneousdeletions in the indicated domains. To generate the pcHA-ID-GSTexpression vector, a DNA fragment encoding the ID of CARD11,corresponding to residues 441 to 671, was cloned into pcDNA3in frame with an N-terminal hemagglutinin (HA)-tag (YPYDVPDYA),and a C-terminal GST derived from pGEX-6P-1 (GE Healthcare).To make the pEBB-HA-ID-GST expression vector, a fragment encodingthe HA-ID-GST fusion was cloned into pEBB, which drives expressionfrom an EF1 ${alpha}$ promoter. pEBG is a derivative of pEBB that expressesGST. Expression vectors for FLAG-tagged proteins were kind giftsfrom G. Nuñez (Bcl10 in pcDNA3), D. Goeddel (TRAF6 inpRK), T. Kawai and S. Akira (TAK1 in pFLAG-CMV4), and M. Boldinand D. Baltimore (IKK ${gamma}$ and caspase-8 C360S in pcDNA3).

RESULTS

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RESULTS

The linker domains in CARD11 are required for regulated TCR signaling to NF- ${kappa}$ B. To examine which domains in CARD11 are required for TCR signalingto NF- ${kappa}$ B, we established a pool of Jurkat T cells that stablyexpresses an shRNA previously shown to knock down expressionof human CARD11 (44). We infected Jurkat T cells with the lentiviralconstruct shown in Fig. 1A and selected for infectants in thepresence of puromycin. Stable expression of the sihCARD11-2hairpin resulted in an approximate 70% reduction in the steady-statelevel of CARD11 protein, while control cells expressing a mutanthairpin or no hairpin displayed wild-type CARD11 levels (Fig.1B left, lower panel). As expected, CARD11-deficient JurkatT cells displayed defects in TCR-mediated activation of NF- ${kappa}$ B,as judged by the relative induction of the NF- ${kappa}$ B-responsive reporterIg ${kappa}$ ₂-IFN-LUC elicited by anti-CD3/anti-CD28 antibodies (Fig.1B, left). In contrast, CARD11-deficient Jurkat T cells displayedno defect in the ability of anti-CD3/anti-CD28 cross-linkingto activate the NFAT-responsive reporter NFAT-LUC (Fig. 1B,right).

Since the sihCARD11-2 hairpin targets the human CARD11 mRNAin a region that contains nucleotides that differ from the murineCARD11 mRNA, we could rescue CARD11 knockdown by cotransfectionof the wild-type murine CARD11, as described previously (44).Using this RNAi rescue assay, we tested a panel of CARD11 deletionmutants for the ability to mediate signaling between the TCRcomplex and NF- ${kappa}$ B. We have previously reported that deletionof the CARD, coiled-coil, SH3, and GUK domains of CARD11 abrogatedthe ability of CARD11 to signal to NF- ${kappa}$ B, while deletion of thePDZ domain had no effect (44) (Fig. 1C depicts the domain structureof CARD11). As shown in Fig. 1D (left), the deletion of severalother regions of the protein also abrogated CARD11 signaling,including the linker between the CARD and coiled-coil domains(L1), the linker between the PDZ and SH3 domains (L3), and thelinker between the SH3 and GUK domains (L4). These three deletionmutants failed to restore CARD11 activity over a wide titrationrange. Western analyses of transfected cells indicated thatthe expression constructs for CARD11 and these deletion variantsresult in comparable levels of protein expression per nanogramof DNA transfected (data not shown).

Interestingly, deletion of the linker between the coiled-coiland PDZ domains resulted in a variant of CARD11 that had a greatlyenhanced ability to signal to NF- ${kappa}$ B (Fig. 1D, right). We thereforetermed this region the ID and the hyperactive variant the ${Delta}$ ID.Recently, Sommer et al. (55) and Matsumoto et al. (32) havedemonstrated that during TCR signaling CARD11 is phosphorylatedin this ID at residues 564, 577, and 657 in a signal-dependentmanner. Residues 564 and 657 can be phosphorylated by PKC ${theta}$ invitro. The kinase responsible for phosphorylation of serine577 has not been reported. The phosphorylation of this ID regionappears to be required for TCR-induced NF- ${kappa}$ B activation and theCARD11-dependent recruitment of Bcl10 and the IKK complex tothe membrane and to lipid rafts (32, 55). Sommer et al. (55)have provided evidence in favor of a model in which the signal-inducedphosphorylation of the ID reverses its inhibitory effect onCARD11 signaling.

In agreement with the studies of Sommer et al. (55), we observedthat the ${Delta}$ ID behaved as a constitutively active CARD11 that hadalready received the activating signal from the TCR complexthat is mediated in part by PKC ${theta}$ (see Fig. S1A in the supplementalmaterial). The ${Delta}$ ID constitutively activated NF- ${kappa}$ B in both JurkatT cells and in human embryonic kidney cells (HEK293T), indicatingthat all of the required components downstream of CARD11 inthe signaling pathway to NF- ${kappa}$ B are present in both lymphoid andnonlymphoid cells (see Fig. S1A and B in the supplemental material).CARD11 may thus be viewed as a cell-type-restricted adapterprotein that functions to couple cell-type-specific upstreamsignaling events to widely expressed downstream machinery.

We found that an ID-GST fusion protein could inhibit the ${Delta}$ IDin trans and could associate with the ${Delta}$ ID (see Fig. S1C and Din the supplemental material). These results suggested thatthe ID inhibits CARD11 by direct interaction with other portionsof the CARD11 protein and that, upon signaling, the ID woulddisengage the other portions of CARD11 and allow the signal-inducedrecruitment of other signaling cofactors.

The ID targets the CARD and the coiled-coil domain. We next determined which domains in CARD11 were required forthe interaction with the ID. A panel of double-deletion variantswas assayed for the ability to associate with the ID-GST fusionwhen coexpressed in HEK293T cells. As shown in Fig. 2, the deletionof the coiled-coil domain had the largest deleterious effecton the binding of the ID-GST fusion to the ${Delta}$ ID. The deletionof the CARD also reduced the level of ID-GST binding, whiledeletions of the other regions of CARD11 did not have significanteffects. No interaction was observed with the GST control. Consistentwith this analysis, an N-terminal construct containing the CARDand coiled-coil regions of CARD11 could associate with the ${Delta}$ ID,but the isolated CARD or the coiled-coil domain could not (datanot shown). These results indicate that the ID binds both theCARD and the coiled-coil domain and that the interaction withboth domains is required for highest affinity binding.

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FIG. 2. Determinants of ID association with the CARD11 ${Delta}$ ID variant. (A) HEK293T cells were transfected with expression vectors for the indicated CARD11 variants and 150 ng of expression vector for either the ID-GST fusion (pEBB-ID-GST) or GST (pEBG). Glutathione-agarose precipitations were performed as described in Materials and Methods. To achieve approximately equivalent expression of each CARD11 variant, the following amounts of each expression vector were used (in ng): wild type (WT), 50; ${Delta}$ ID, 50; ${Delta}$ ID ${Delta}$ CARD, 1,000; ${Delta}$ ID ${Delta}$ L1, 150; ${Delta}$ ID ${Delta}$ CC, 75; ${Delta}$ ID ${Delta}$ PDZ, 100; ${Delta}$ ID ${Delta}$ L3, 150; ${Delta}$ ID ${Delta}$ SH3, 150; ${Delta}$ ID ${Delta}$ L4, 100; ${Delta}$ ID ${Delta}$ GUK, 100. Western blotting (WB) with the indicated antibodies was performed to develop the contents of the precipitate (top and bottom panels) and the lysate input (middle panel). ${alpha}$ , anti.

The CARD11 domains that function in NF- ${kappa}$ B activation downstream of ID neutralization. Our results and those of a previous study (44) indicated thatthe CARD, L1, coiled-coil, L3, SH3, L4, and GUK domains areeach required for NF- ${kappa}$ B activation by TCR signaling. Each CARD11domain that is required for TCR-mediated NF- ${kappa}$ B activation could,in principle, act at several levels of the pathway. As partof the scaffolding function of CARD11, a domain may coordinateand be required for signaling events upstream of PKC ${theta}$ activation.For example, the GUK domain of CARD11 is required for associationwith the PDK1 kinase, which has been reported to phosphorylateand activate PKC ${theta}$ in this pathway (27). It is possible that otherdomains of CARD11 function to coordinate events upstream ofPKC ${theta}$ activation. Alternatively, a domain in CARD11 might be requiredfor the derepressive action of PKC ${theta}$ on CARD11. For example, adomain in CARD11 might mediate a protein-protein interactionthat is required for the efficient association of active PKC ${theta}$ with CARD11 to enable the phosphorylation of the ID and theresulting derepression of CARD11. Finally, a domain in CARD11might be required for events downstream of ID domain phosphorylationand neutralization to coordinate or activate proteins that acton the IKK complex.

If a domain were required exclusively for events that activatePKC ${theta}$ kinase activity, we expected that it would be required forTCR signaling to NF- ${kappa}$ B but not be required for NF- ${kappa}$ B activationby PMA/ionomycin treatment, which can bypass the requirementsfor upstream molecules, presumably by activating PKC ${theta}$ directly.Therefore, we used the RNAi rescue assay described in Fig. 1to test whether each domain that was required for NF- ${kappa}$ B activationby anti-CD3/anti-CD28 cross-linking was also required for PMA-ionomycin-mediatedactivation. As shown in Fig. 3A, the CARD, L1, coiled-coil,L3, SH3, L4, and GUK domains were required for optimal activationof the Ig ${kappa}$ ₂-IFN-LUC reporter by PMA/ionomycin treatment in JurkatT cells, indicating that these domains are required for eventsdownstream of PKC ${theta}$ activation.

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FIG. 3. CARD11 domain requirements for NF- ${kappa}$ B activation by PMA/ionomycin treatment and by the CARD11 ${Delta}$ ID variant. (A) Jurkat T cell pools stably expressing either no hairpin (–), the siMUT shRNA, or the sihCARD11-2 shRNA were transfected with 200 ng of pCSK-LacZ and 1,800 ng of Ig ${kappa}$ ₂-IFN-LUC in the absence or presence of 200 ng of the indicated CARD11 variant expression construct. Cells were stimulated with PMA and ionomycin as indicated. (B) Wild-type Jurkat T cells were transfected with 200 ng of pCSK-LacZ and 2,500 ng of Ig ${kappa}$ ₂-IFN-LUC in the presence of the indicated amounts (in ng) of expression vectors for the indicated CARD11 variants. (C) HEK293T cells were transfected with 6 ng of pCSK-LacZ and 20 ng of Ig ${kappa}$ ₂-IFN-LUC in the presence of the indicated amounts (in ng) of expression vectors for the indicated CARD11 variants. (D) The lysates from samples in panel C were probed by Western blotting using anti-myc primary antibody to indicate the relative expression level of each variant. The bars represent the mean values of triplicate samples, and error bars indicate the standard deviations. WT, wild type.

If a domain were required exclusively for the action of activatedPKC ${theta}$ on CARD11, for PKC ${theta}$ -mediated neutralization of the ID, thenthe domain should be required for TCR- and PMA/ionomycin-mediatedreporter stimulation but not for reporter stimulation by the ${Delta}$ ID, which does not require PKC ${theta}$ action or ID neutralization foractivity. We therefore deleted each domain in the context ofthe ${Delta}$ ID and tested the effect of the deletion on the abilityof the protein to activate the Ig ${kappa}$ ₂-IFN-LUC reporter in JurkatT cells (Fig. 3B) and HEK293T cells (Fig. 3C). Interestingly,each domain tested, with the exception of the PDZ domain, wasrequired for maximal ${Delta}$ ID activity in both lymphoid and nonlymphoidcell types. These results indicate that the CARD, L1, coiled-coil,L3, SH3, L4, and GUK domains each function, directly or indirectly,in CARD11 signaling to NF- ${kappa}$ B downstream of ID neutralization.

The ID regulates the association of CARD11 with Bcl10, TRAF6, TAK1, IKK ${gamma}$ , and caspase-8. Several widely expressed signaling proteins have been implicatedin TCR-mediated activation of the IKK complex, including Bcl10,MALT1, TRAF2, TRAF6, caspase-8, and TAK1. During antigen receptorsignaling, CARD11 has been shown to associate with Bcl10 (17,69), TAK1 (53), and the IKK ${gamma}$ subunit of the IKK complex (56).We suspected that the ID might regulate the ability of CARD11to associate with one or more of these signaling cofactors.Indeed, Sommer et al. (55) have demonstrated that the ID canregulate the association of CARD11 with Bcl10. We also observedan enhanced ability of the CARD11 ${Delta}$ ID variant to associate withBcl10 compared to wild-type CARD11. We coexpressed myc-tagged ${Delta}$ ID and wild-type CARD11 with FLAG-tagged Bcl10 and assayed associationby coimmunoprecipitation using anti-FLAG antibodies. As shownin Fig. 4A, we readily detected the CARD11 ${Delta}$ ID variant in theimmunoprecipitate while wild-type CARD11 was barely detected.

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FIG. 4. The ID regulates the ability of CARD11 to associate with Bcl10, TRAF6, TAK1, IKK ${gamma}$ , and caspase-8. HEK293T cells were transfected with 50 to 150 ng of the expression vector for wild-type CARD11 or the ${Delta}$ ID in the absence and presence of vectors encoding FLAG-tagged versions of Bcl10 (100 ng), TRAF6 (200 ng), TAK1 (200 ng), IKK ${gamma}$ (1,000 ng), or caspase-8 C360S (1,000 ng), as indicated. Anti-FLAG immunoprecipitations were performed as described in Materials and Methods. In each panel, Western blotting (WB) with the indicated antibodies (at right) was performed to develop the contents of the immunoprecipitate (top and bottom) and the lysate input (middle). WT, wild type; ${alpha}$ , anti; IP, immunoprecipitation.

Interestingly, we found that the ${Delta}$ ID also had an enhanced ability,compared to wild-type CARD11, to associate with TRAF6 (Fig.4B), TAK1 (Fig. 4C), IKK ${gamma}$ (Fig. 4D), and caspase-8 (Fig. 4E)using the same immunoprecipitation assay. TRAF6, IKK ${gamma}$ , and caspase-8appeared to associate only with the ${Delta}$ ID, indicating a strongability of the ID to regulate the association of CARD11 withthese proteins. TAK1 appeared to be somewhat less susceptibleto ID regulation for CARD11 association since there was lessof a difference between the wild type and the ${Delta}$ ID in parallelimmunoprecipitations. For these experiments we used the catalyticallyinactive C360S variant of caspase-8 so as not to cause apoptosisin the transfected cells. In similar experiments, we did notdetect a reproducible association between the ${Delta}$ ID and eitherTRAF2 or MALT1 (data not shown). These results indicate thatthe ID regulates the ability of CARD11 to associate with multiplesignaling cofactors.

To test whether the ID directly competes for binding of thesecofactors to CARD11, we assessed in glutathione-agarose precipitationswhether the interaction between the ID-GST fusion and the ${Delta}$ IDwould be affected by coexpression of any of these cofactors.As shown in Fig. 5, Bcl10, IKK ${gamma}$ , TRAF6, and TAK1 did reduce theinteraction between ID and the ${Delta}$ ID, consistent with a model inwhich the ID sterically interferes with the binding of thesefactors to CARD11. Caspase-8 did not reduce the ID- ${Delta}$ ID interaction;this might suggest that caspase-8 associates with CARD11 througha bridging protein that is endogenous to 293T cells. Alternatively,the affinity of caspase-8 for the ${Delta}$ ID or its expression levelmight be too low to achieve competition with the ID under theconditions of this experiment. Consistent with mutually exclusivebinding of the ID or these cofactors with the ${Delta}$ ID, we did notdetect any of the FLAG-tagged cofactors in the glutathione-agaroseprecipitates containing the ID-GST (data not shown).

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FIG. 5. Bcl10, TRAF6, TAK1, and IKK ${gamma}$ compete with the ID in trans for binding to the ${Delta}$ ID variant. HEK293T cells were transfected with expression vectors for the ${Delta}$ ID and either the ID-GST fusion or GST in the absence and presence of vectors encoding Bcl10 (A), IKK ${gamma}$ (B), TRAF6 (C), TAK1 (D), or caspase-8 C360S (E). Glutathione-agarose precipitations were performed as described in Materials and Methods. To achieve approximately equivalent expression of the ${Delta}$ ID and the ID-GST in the absence and presence of each signaling cofactor, the following amount of each expression vector was used (in ng): ${Delta}$ ID, 50 to 100; ID-GST, 100 to 300; GST, 50; Bcl10, 150; IKK ${gamma}$ , 300; TRAF6, 300; TAK1, 100; or caspase-8 C360S, 300. The panels show the contents of the precipitate and lysate input, developed with anti-myc, anti-FLAG, or anti-GST primary antibody, as indicated. ${alpha}$ , anti; WB, Western blotting.

Inducible association of CARD11 with caspase-8 and TRAF6 in T cells. While it has previously been demonstrated that CARD11 can associatewith the IKK complex, Bcl10, and TAK1 in a signal-induciblemanner during antigen receptor signaling in lymphocytes, suchan interaction has not been reported for caspase-8 and TRAF6.The ability of the ID to regulate CARD11 association with caspase-8and TRAF6 predicts that, in T cells, the neutralization of theID during TCR signaling should result in the inducible associationof these proteins with CARD11. To test this prediction, we treatedJurkat T cells with a time course of PMA/ionomycin, performedimmunoprecipitations from extracts using either anti-TRAF6 oranti-caspase-8 antibody, and probed for the presence of CARD11.As shown in Fig. 6, CARD11 associated with these proteins ina signal-inducible manner.

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FIG. 6. Signal-induced association of CARD11 with TRAF6 and caspase-8 in T cells. Jurkat T cells were stimulated with a time course of PMA/ionomycin as indicated. Anti-TRAF6 or anti-caspase-8 immunoprecipitations were performed as described in Materials and Methods. In each panel, Western blotting (WB) with the indicated antibodies (at right) was performed to develop the contents of the immunoprecipitate (top and bottom) and the lysate input (middle). The asterisk indicates an undefined inducible band in the immunoprecipitate that is reactive to the anti-CARD11 primary antibody. ${alpha}$ , anti; IP, immunoprecipitation.

The ID does not determine whether CARD11 can oligomerize. Tanner et al. (62) have reported that the coiled-coil domainof CARD11 mediates oligomerization of the protein. Since theID interacted with the coiled-coil domain, we tested whetherthe ID could regulate the ability of CARD11 to oligomerize.When myc-tagged and FLAG-tagged wild-type CARD11 were coexpressedin HEK293T cells, the proteins readily associated, as revealedin the coimmunoprecipitation experiment shown in Fig. 7. Thehyperactive ${Delta}$ ID variant displayed no further enhanced oligomerizationat comparable protein concentrations, indicating that the IDand signals that regulate the interaction between the ID andthe coiled-coil domain do not significantly regulate the oligomerizationstatus of CARD11.

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FIG. 7. The ID does not determine whether CARD11 can self-associate. HEK293T cells were transfected with the indicated amounts (in ng) of expression vectors for wild-type CARD11 or the ${Delta}$ ID variant as either myc-tagged or FLAG-tagged fusions. Anti-FLAG immunoprecipitations were performed as described in Materials and Methods. The panels show the contents of the immunoprecipitate and the lysate input, developed with either anti-myc or anti-FLAG primary antibody, as indicated. WT, wild type; ${alpha}$ , anti; IP, immunoprecipitation; WB, Western blotting.

Determinants of ID-regulated association of signaling cofactors with CARD11. The enhanced ability of the ${Delta}$ ID to associate with Bcl10, TRAF6,TAK1, caspase-8, and IKK ${gamma}$ afforded the opportunity to ascriberecruitment functions to the domains revealed in Fig. 3 to berequired for signaling downstream of ID neutralization. We usedthe immunoprecipitation assay and a panel of double deletionvariants of CARD11 to determine which domains of the ${Delta}$ ID arerequired for the association of Bcl10, TRAF6, TAK1, caspase-8C360S, and IKK ${gamma}$ . As shown in Fig. 8A, the deletion of eitherthe CARD or coiled-coil domain in the context of the ${Delta}$ ID abrogatedthe association of Bcl10, indicating that both the CARD andthe coiled-coil domain of CARD11 are required for high-affinityassociation with Bcl10. None of the other domain deletions appearedto affect the association of Bcl10 with the ${Delta}$ ID.

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FIG. 8. Determinants of the association of the ${Delta}$ ID with Bcl10, TRAF6, and TAK1. (A) HEK293T cells were transfected with expression vectors for the indicated CARD11 variants in the absence (–) or presence (+) of the expression vector for FLAG-tagged Bcl10. Anti-FLAG immunoprecipitations were performed as described in Materials and Methods. To achieve approximately equivalent expression of each CARD11 variant, the following amount of each expression vector was used (in ng): wild type (WT), 100; ${Delta}$ ID, 100; ${Delta}$ ID ${Delta}$ CARD, 1,000; ${Delta}$ ID ${Delta}$ L1, 100; ${Delta}$ ID ${Delta}$ CC, 100; ${Delta}$ ID ${Delta}$ PDZ, 150; ${Delta}$ ID ${Delta}$ L3, 125; ${Delta}$ ID ${Delta}$ SH3, 150; ${Delta}$ ID ${Delta}$ L4, 50; ${Delta}$ ID ${Delta}$ GUK, 50. To achieve approximately equivalent expression of Bcl10 in each sample, 100 ng of Bcl10 expression vector was used in each sample except that 500 ng was used in the ${Delta}$ ID ${Delta}$ CARD sample and 300 ng was used in the ${Delta}$ ID ${Delta}$ PDZ sample. Western blotting (WB) with the indicated antibodies (at right) was performed to develop the contents of the immunoprecipitate (top and bottom panels) and the lysate input (middle panel). (B) Anti-FLAG immunoprecipitations were performed as described in panel A except that 200 ng of the expression vector for FLAG-tagged TRAF6 was used in all indicated samples (+). The following amount (in ng) of expression vector for each CARD11 variant was used: WT, 200; ${Delta}$ ID, 200; ${Delta}$ ID ${Delta}$ CARD, 2,000; ${Delta}$ ID ${Delta}$ L1, 200; ${Delta}$ ID ${Delta}$ CC, 90; ${Delta}$ ID ${Delta}$ PDZ, 300; ${Delta}$ ID ${Delta}$ L3, 250; ${Delta}$ ID ${Delta}$ SH3, 300; ${Delta}$ ID ${Delta}$ L4, 100; ${Delta}$ ID ${Delta}$ GUK, 100. (C) Anti-FLAG immunoprecipitations were performed as described in panel A except that 200 ng of the expression vector for FLAG-tagged TAK1 was used in all indicated samples (+). The following amount (in ng) of expression vector for each CARD11 variant was used: WT, 100; ${Delta}$ ID, 100; ${Delta}$ ID ${Delta}$ CARD, 1,000; ${Delta}$ ID ${Delta}$ L1, 100; ${Delta}$ ID ${Delta}$ CC, 100; ${Delta}$ ID ${Delta}$ PDZ, 150; ${Delta}$ ID ${Delta}$ L3, 175; ${Delta}$ ID ${Delta}$ SH3, 150; ${Delta}$ ID ${Delta}$ L4, 50; ${Delta}$ ID ${Delta}$ GUK, 50. ${alpha}$ , anti; IP, immunoprecipitation.

In the assay for TRAF6 association with the ${Delta}$ ID, the deletionof the coiled-coil domain had the largest deleterious effect(Fig. 8B). In addition, the deletion of the CARD and the L1domain also reduced the ability of TRAF6 to associate with the ${Delta}$ ID.

Interestingly, TAK1 association with the ${Delta}$ ID was affected inthis assay only by deletion of the CARD and not by deletionof any other domain (Fig. 8C). Caspase-8 C360S association withthe ${Delta}$ ID was abrogated by deletion of the coiled-coil domain andpartially affected by deletion of the CARD (Fig. 9A). IKK ${gamma}$ showeda pattern similar to that of caspase-8; its association withthe ${Delta}$ ID was eliminated by deletion of the coiled-coil domainand reduced to a lesser extent by deletion of the CARD (Fig.9B).

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FIG. 9. Determinants of the association of the ${Delta}$ ID with caspase-8 C360S and IKK ${gamma}$ . (A) Anti-FLAG immunoprecipitations were performed as described in the legend of Fig. 8A except that 1,000 ng of the expression vector for FLAG-tagged caspase-8 C360S was used in all indicated samples (+). The following amount (in ng) of expression vector for each CARD11 variant was used: wild type (WT), 100; ${Delta}$ ID, 100; ${Delta}$ ID ${Delta}$ CARD, 1,000; ${Delta}$ ID ${Delta}$ L1, 100; ${Delta}$ ID ${Delta}$ CC, 50; ${Delta}$ ID ${Delta}$ PDZ, 150; ${Delta}$ ID ${Delta}$ L3, 125; ${Delta}$ ID ${Delta}$ SH3, 150; ${Delta}$ ID ${Delta}$ L4, 50; ${Delta}$ ID ${Delta}$ GUK, 50. (B) Anti-FLAG immunoprecipitations were performed as described in the legend of Fig. 8A except that 800 ng of the expression vector for FLAG-tagged IKK ${gamma}$ was used in all indicated samples (+). The following amount (in ng) of expression vector for each CARD11 variant was used: WT, 120; ${Delta}$ ID, 120; ${Delta}$ ID ${Delta}$ CARD, 1,200; ${Delta}$ ID ${Delta}$ L1, 120; ${Delta}$ ID ${Delta}$ CC, 120; ${Delta}$ ID ${Delta}$ PDZ, 180; ${Delta}$ ID ${Delta}$ L3, 210; ${Delta}$ ID ${Delta}$ SH3, 180; ${Delta}$ ID ${Delta}$ L4, 60; ${Delta}$ ID ${Delta}$ GUK, 60. ${alpha}$ , anti; IP, immunoprecipitation; WB, Western blotting.

Although these proteins in general showed different relativedomain dependencies for their association with the hyperactiveCARD11 ${Delta}$ ID variant, each required either the CARD or the coiled-coildomain or both for association. These are the same domains thatappeared from our analysis in Fig. 2 to be targeted for bindingby the ID.

Bcl10 is not required for the association of TAK1, TRAF6, caspase-8, or IKK ${gamma}$ with activated CARD11 in HEK293T cells. Recent models of CARD11 action in antigen receptor signalinghave proposed that the binding of Bcl10 and MALT1 to CARD11is required for the recruitment of other signaling cofactorsinto an active signaling complex. In these models, a Bcl10-MALT1complex binds directly to CARD11 during signaling and then bridgesan interaction between CARD11 and other factors that directlybind to either Bcl10 or Bcl10-bound MALT1, such as TRAF6, caspase-8,and the IKK complex (22, 43, 45, 63). However, the domain requirementsfor the association of cofactors with the ${Delta}$ ID suggested thatseveral proteins may associate with CARD11 in a Bcl10-independentmanner. The coiled-coil domain deletion had a greater effecton Bcl10 association than on TAK1 association (Fig. 8), andthe CARD deletion had a greater effect on Bcl10 associationthan on TRAF6, caspase-8 C360S, or IKK ${gamma}$ association with the ${Delta}$ ID (Fig. 8 and 9).

We therefore tested whether the Bcl10 that is endogenously expressedin HEK293T cells was required for the observed association betweenthe hyperactive ${Delta}$ ID and TAK1, TRAF6, caspase-8 C360S, or IKK ${gamma}$ .We infected HEK293T cells with a lentivirus that stably expressesan shRNA designed to knock down human Bcl10 by RNAi (see Materialsand Methods for experimental details). As shown in Fig. 10A,expression of this hairpin resulted in approximately 90% knockdownof endogenous Bcl10 expression in this cell line (KD-Bcl10)compared to a control line infected with a lentivirus expressinga hairpin designed to knock down GFP (KD-GFP). As expected,this reduction in Bcl10 expression severely impaired the abilityof the ${Delta}$ ID or wild-type CARD11 to activate the Ig ${kappa}$ ₂-IFN-LUC reporterwhen expressed at levels of protein expression comparable tothat in the KD-GFP control line (Fig. 10B and C). We then determinedwhether this reduction in Bcl10 levels, which so drasticallyimpaired ${Delta}$ ID signaling to NF- ${kappa}$ B, would affect the ability of the ${Delta}$ ID to bind to other signaling cofactors. Surprisingly, therewas no significant difference in the ability of the ${Delta}$ ID to interactwith TAK1 (Fig. 11A), TRAF6 (Fig. 11B), IKK ${gamma}$ (Fig. 12A), or caspase-8C360S (Fig. 12B) in the Bcl10-deficient line compared to interactionobserved in control KD-GFP line. These experiments were conductedusing subsaturating levels of the interacting proteins in orderto maximize the detection of any effect of Bcl10 deficiency.Consistent with a Bcl10-independent association of these proteinswith the ${Delta}$ ID, we did not detect Bcl10 in the immunoprecipitatedcomplexes that contained the ${Delta}$ ID and either TAK1, caspase-8 C360S,TRAF6, or IKK ${gamma}$ in either the KD-GFP or KD-Bcl10 lines (Fig. 11and 12). These data indicate that the hyperactive ${Delta}$ ID, whichcorresponds to CARD11 that has been activated by signal-inducedID neutralization, has an enhanced ability to associate withthese cofactors that does not depend on Bcl10.

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FIG. 10. Stable knockdown of Bcl10 and MALT1 in HEK293T cell lines. HEK293T cells were infected with lentiviruses expressing shRNAs that target either Bcl10, MALT1, or GFP as a control, as described in Materials and Methods, to establish the KD-GFP, KD-Bcl10, and KD-MALT1 cell lines. (A) The indicated amounts (in µg) of stably infected cell lysates were assayed by Western blotting for Bcl10 and MALT1 protein levels using anti-Bcl10 and anti-MALT1 primary antibodies. (B) The KD-GFP, KD-Bcl10, and KD-MALT1 cell lines were transfected with 6 ng of pCSK-LacZ, 20 ng of Ig ${kappa}$ ₂-IFN-LUC, and the indicated amounts (in ng) of expression vectors for myc-tagged wild-type CARD11 or the ${Delta}$ ID variant. Stimulation was determined as described in Materials and Methods. (C) The lysates from samples in panel B were probed by Western blotting using anti-myc primary antibody to indicate the relative expression level of each variant. The bars represent the mean values of triplicate samples, and error bars indicate the standard deviations. WT, wild type.

We also determined whether the MALT1 that is endogenously expressedin HEK293T cells was required for the observed association betweenthe hyperactive ${Delta}$ ID and TAK1, TRAF6, caspase-8 C360S, or IKK ${gamma}$ .HEK293T cells were infected with a lentivirus expressing a hairpinthat targets the human MALT1 mRNA (see Materials and Methodsfor experimental details). As shown in Fig. 10A, infection withthis virus resulted in a cell line, KD-MALT1, that demonstrateda $~$ 87% reduction in MALT1 protein levels. Interestingly, thisreduction in MALT1 expression resulted in only a mild, approximatelytwofold reduction in the ability of wild-type CARD11 or the ${Delta}$ ID to activate the Ig ${kappa}$ ₂-IFN-LUC reporter (Fig. 10B) at equivalentlevels of protein expression in the KD-GFP and KD-MALT1 lines(Fig. 10C). This result indicates either that the residual levelsof MALT1 ( $~$ 13% of wild-type levels) are largely sufficient toconduct CARD11-mediated signaling to NF- ${kappa}$ B or that MALT1 is notstrictly required in this context for CARD11-mediated signalingto NF- ${kappa}$ B. Interestingly, Ferch et al. (16) have recently shownthat in B cells MALT1 is dispensable for CARD11-mediated IKKactivation and for the activation of RelA-containing NF- ${kappa}$ B complexes.In contrast, MALT1 is required for B-cell receptor-mediatedactivation of c-Rel-containing NF- ${kappa}$ B heterodimers. It is possiblethat HEK293T cells rely mainly on RelA-containing heterodimersfor NF- ${kappa}$ B activity.

As shown in Fig. 11 and 12, the $~$ 87% reduction in MALT1 proteinlevels did not affect the ability of the ${Delta}$ ID to interact withTAK1, TRAF6, caspase-8 C360S, or IKK ${gamma}$ . Additionally, we did notdetect MALT1 in the immunoprecipitated complexes that containedthe ${Delta}$ ID and either TAK1, TRAF6, caspase-8 C360S, or IKK ${gamma}$ in eitherthe KD-GFP, KD-Bcl10, or KD-MALT1 lines. These data indicatethat an eightfold reduction in MALT1 levels does not significantlyaffect the ability of the ${Delta}$ ID to interact with these proteinsunder these conditions.

Differential dependence on Bcl10 and MALT1 for the signal-induced association of CARD11 with TRAF6, the IKK complex, and caspase-8 in T cells. We then determined whether Bcl10 and MALT1 were required forthe signal-induced association of cofactors with CARD11 in Tcells. We infected Jurkat T cells with the same lentivirusesused in the experiment shown in Fig. 10 and obtained Jurkatlines that exhibited $~$ 83% reduced expression of Bcl10 (KD-Bcl10)and MALT1 (KD-MALT1) (Fig. 13A). Each of these lines was defectivein PMA/ionomycin-induced activation of NF- ${kappa}$ B, as judged by I ${kappa}$ B ${alpha}$ degradation (Fig. 13B) and Ig ${kappa}$ ₂-IFN-LUC reporter stimulation(Fig. 13C), indicating that this level of knockdown of eitherBcl10 or MALT1 in Jurkat T cells impaired CARD11-dependent signaling.As shown in Fig. 14A, despite the 83% reduction in Bcl10 orMALT1, there was no defect in the PMA/ionomycin-induced associationbetween CARD11 and TRAF6 in the KD-Bcl10 or KD-MALT1 JurkatT cell lines, as indicated by the coimmunoprecipitation of CARD11with TRAF6 using anti-TRAF6 antibodies. This result confirmedthat, at endogenous protein concentrations in T cells, neitherBcl10 nor MALT1 is required for the signal-induced associationof CARD11 and TRAF6.

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FIG. 13. Stable knockdown of Bcl10 and MALT1 in Jurkat T cell lines. Jurkat T cells were infected with lentiviruses expressing shRNAs that target either Bcl10, MALT1, or GFP as a control, as described in Materials and Methods, to establish the KD-GFP, KD-Bcl10, and KD-MALT1 cell lines. (A) The indicated amounts (in µg) of stably infected cell lysates were assayed by Western blotting for Bcl10 and MALT1 protein levels using anti-Bcl10 and anti-MALT1 primary antibodies. (B) The KD-GFP, KD-Bcl10, and KD-MALT1 cell lines were stimulated with PMA (50 ng/ml) and ionomycin (1 µM) (P/I) for the indicated times. Lysates were assayed by Western blotting for I ${kappa}$ B ${alpha}$ degradation using anti-I ${kappa}$ B ${alpha}$ primary antibody. (C) The KD-GFP, KD-Bcl10, and KD-MALT1 cell lines were transfected with 200 ng of pCSK-LacZ, 1,500 ng of Ig ${kappa}$ ₂-IFN-LUC, and 1,300 ng of pBSKII+ and stimulated with 50 ng/ml PMA and 1 µM ionomycin for 1 h. Stimulation was determined as described in Materials and Methods. The bars represent the mean values of triplicate samples, and error bars indicate the standard deviations.

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FIG. 14. Effect of Bcl10 and MALT1 knockdown on the inducible association of CARD11 with cofactors in Jurkat T cells. The KD-GFP, KD-Bcl10, and KD-MALT1 cell lines were stimulated with a time course of PMA-ionomycin (P/I) as indicated. Anti-TRAF6 (A), anti-IKK ${alpha}$ (B), and anti-caspase-8 (C) immunoprecipitations were performed as described in Materials and Methods. In each panel, Western blotting (WB) with the indicated antibodies (at right) was performed to develop the contents of the immunoprecipitate (top and bottom) and the lysate input (middle). ${alpha}$ , anti; IP, immunoprecipitation.

We assessed the association of the IKK complex with CARD11 inthese lines by immunoprecipitation with anti-IKK ${alpha}$ antibodies.As shown in Fig. 14B, the signal-induced association of theIKK complex with CARD11 was only partially reduced in the KD-Bcl10and KD-MALT1 lines, indicating that the recruitment of the IKKcomplex to CARD11 is largely independent of Bcl10 and MALT1.

In sharp contrast, the inducible coimmunoprecipitation of CARD11with caspase-8 was severely affected by the knockdown of eitherBcl10 or MALT1 (Fig. 14C), indicating that both Bcl10 and MALT1are required for caspase-8 to stably associate with CARD11 duringsignaling. These results indicate that at endogenous levelsof expression in T cells, during the signal-induced conversionof CARD11 to an active scaffold, CARD11 can recruit cofactorsindependently of one another in a manner that differentiallydepends on Bcl10 and MALT1.

DISCUSSION

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DISCUSSION

CARD11 is a critical adapter molecule that functions to couplethe recognition of antigen and costimulatory signals at thesurface of the T cell to the induction of NF- ${kappa}$ B activity thatis required for T-cell activation and proliferation in the adaptiveimmune response. As a signaling adapter, CARD11 must containdeterminants that allow it to receive pathway-specific upstreamsignals and transmit the information to non-pathway-specificmolecules that are used widely for the activation of the IKKcomplex and NF- ${kappa}$ B.

Our results illuminate how CARD11 is converted from an inactivestate to an active signaling scaffold so that upstream TCR signalingis translated into the assembly of an active signaling complex(Fig. 15). Prior to signaling, the ID interacts with the CARDand the coiled-coil domain to prevent the recruitment of signalingcofactors to CARD11. The interaction of the ID with the CARDand the coiled-coil domain may occur within the same CARD11molecule or between two or more oligomerized molecules of CARD11.Signaling downstream of the TCR results in the neutralizationof the activity of the ID, which requires the phosphorylationof the ID on serine residues 564 and 657 by PKC ${theta}$ and on serine577 by an undetermined kinase (32, 55). Once the ID is neutralized,the CARD, L1, and coiled-coil domains present surfaces for therecruitment of Bcl10, TAK1, TRAF6, caspase-8, and IKK ${gamma}$ . MALT1is presumably recruited through its interaction with Bcl10,and caspase-8 stably associates during signaling in a Bcl10-and MALT1-dependent manner. These factors then function to promotethe activation of the IKK complex and NF- ${kappa}$ B, which other investigatorshave shown to involve the TRAF6-mediated ubiquitination of MALT1(43) and IKK ${gamma}$ (59), the MALT1-mediated ubiquitination of IKK ${gamma}$ (73), the ubiquitination of Bcl10 by an undetermined ligase(71), the TAK1-mediated phosphorylation of IKKβ (52, 59),and the proteolytic activity of caspase-8 on an undefined substrate(58).

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FIG. 15. Model of the signal-induced conversion of CARD11 to an active signaling scaffold. Prior to TCR engagement, the ID of CARD11 interacts with the CARD and the coiled-coil (CC) domain to prevent the association of signaling cofactors. Although it is depicted here as an intramolecular interaction in the inhibited state, it is also possible that the ID interacts with the CARD and the coiled-coil domain of another CARD11 molecule in the oligomer. TCR signaling leads to the neutralization of ID activity, in part through the phosphorylation of the ID by PKC ${theta}$ . Once the ID is neutralized, signaling cofactors can be recruited to the N-terminal portion of CARD11. The model indicates which domains of CARD11 are required for the association with the cofactors analyzed. TAK1 requires only the CARD, while Bcl10 requires the CARD and coiled-coil domain. TRAF6 requires the CARD and the L1 and coiled-coil domains, while caspase-8 and IKK ${gamma}$ each require the CARD and the coiled-coil domain. MALT1 is presumably recruited through interactions with Bcl10. Caspase-8 (CASP-8) requires both Bcl10 and MALT1 to associate with CARD11 during signaling. The association of TAK1, TRAF6, and IKK ${gamma}$ with activated CARD11 can occur in a Bcl10-independent and MALT1-independent manner. The ID does not appear to influence whether CARD11 oligomerizes, suggesting that oligomerization occurs both before and after signaling through a region of the coiled-coil domain that is not targeted by the ID. The depicted interactions between CARD11 and signaling cofactors may be direct or may require other proteins to bridge the associations.

It is important to note that our association studies do notdistinguish between direct and indirect association betweenCARD11 and these cofactors since the experiments were performedusing cell lysates. Other proteins that are present in HEK293Tand Jurkat T cells may bridge the interactions we studied.

The determinants in CARD11 that control its association withBcl10, TAK1, TRAF6, IKK ${gamma}$ , and caspase-8 lie within the CARD-L1-coiled-coilregion (Fig. 15). The ${Delta}$ ID hyperactive variant, which correspondsto activated CARD11 in which the ID has been neutralized, requiredboth the CARD and the coiled-coil domain to associate with Bcl10.The TAK1 association required only the CARD, while the TRAF6association required the CARD, L1, and coiled-coil domains.The association of IKK ${gamma}$ and caspase-8 required the coiled-coildomain and, to a lesser extent, the CARD. Bcl10, TAK1, and IKK ${gamma}$ have previously been shown to associate with CARD11 in an induciblemanner during antigen receptor signaling (17, 53, 56, 69). Ourobservation that the ${Delta}$ ID had an enhanced ability to associatewith TRAF6 and caspase-8 compared to wild-type CARD11 predictedthat both of these proteins would also associate with CARD11in T cells in a signal-dependent manner. This was indeed thecase (Fig. 6). Caspase-8 and TRAF6 have been shown to interact,and this interaction may be important for signaling events thatoccur subsequent to their recruitment to CARD11 (4).

Although the ID regulates the association of multiple cofactorswith CARD11, it does not appear to regulate CARD11 oligomerization.Both wild-type and ${Delta}$ ID variants of CARD11 appeared to have equivalentcapacities to self-associate (Fig. 7). We have shown that thecoiled-coil domain is targeted by the ID, and Tanner et al.have demonstrated that the coiled-coil domain is required forCARD11 oligomerization (62). This indicates that CARD11 oligomerizationis likely mediated by surfaces of the coiled-coil domain thatare not engaged by the ID and is not influenced by signals thatneutralize activity of the ID.

Recent models have proposed that during TCR signaling, Bcl10is recruited to CARD11 and functions to recruit other signalingcofactors into a CARD11-containing complex so that IKK complexactivation may proceed (43, 45, 51, 52, 63). Our data in HEK293Tcells indicate that once the ID is neutralized, CARD11 has anintrinsic enhanced affinity for TAK1, TRAF6, caspase-8, andIKK ${gamma}$ and can recruit these molecules in a Bcl10-independent manner(Fig. 10 to 12).

In Jurkat T cells, the signal-induced recruitment of TRAF6 andthe IKK complex to CARD11 were largely Bcl10 and MALT1 independent(Fig. 13 and 14), consistent with a Bcl10- and MALT1-independentability of CARD11 to associate with these cofactors once theID is neutralized by upstream signaling. In contrast, the inducibleassociation of caspase-8 with CARD11 in T cells exhibited amuch greater dependence on Bcl10 and MALT1 than the other factorsexamined (Fig. 14). This observation was surprising since the ${Delta}$ ID could associate with caspase-8 C360S in HEK293T cells ina manner that was not affected by the $~$ 90% reduction in Bcl10or MALT1 levels. The difference might be explained by the factthat we assayed association in HEK293T cells using the catalyticallyinactive C360S variant of caspase-8. Caspase-8 is known to undergoconformational changes after the activation of its proteolyticactivity (6). Since caspase-8 is activated during TCR signaling,it is likely that the associations we detected in Jurkat T cellsinvolved catalytically active caspase-8. It is possible thatthe inactive conformation of caspase-8 can be recruited to CARD11during signaling in a Bcl10-independent manner and then convertto the active conformation which stably associates with CARD11through Bcl10 and MALT1. We were not able to reproducibly assaythe signal-induced recruitment of TAK1 to CARD11 in Jurkat Tcells with the available anti-TAK1 antibodies. However, theCARD11-TAK1 association was not as inhibited by the ID in cisas were the other cofactor associations, and TAK1 required onlythe CARD for association with the ${Delta}$ ID, while the other factorsrequired other domains. These data strongly suggest that TAK1is recruited to CARD11 in a manner that is independent of theother factors we studied.

The association of Bcl10, TAK1, TRAF6, IKK ${gamma}$ , and caspase-8 withthe CARD and with the L1 and coiled-coil domains explains whythese domains of CARD11 are required after the inhibitory activityof the ID is neutralized by upstream signals. We also demonstratedthat each of the L3, SH3, L4, and GUK domains of CARD11 is alsonecessary for signaling after ID neutralization. Each of thesedomains is required for PMA/ionomycin-mediated signaling toNF- ${kappa}$ B in T cells, and each is required for constitutive signalingby the CARD11 ${Delta}$ ID (Fig. 3).

The L3, SH3, L4, and GUK domains may mediate the recruitmentof other factors required for IKK complex activation, may targetCARD11 and associated factors to a cellular locale that is requiredfor signaling, or may promote conformational states of the CARDand the coiled-coil domain that are required to bind cofactorsthat we did not study. All of these domains are required forthe activity of the ${Delta}$ ID in both lymphoid and nonlymphoid cells,indicating that they function in concert with factors that arenot specific to the antigen-receptor signaling pathway and donot depend on the specific spatial architecture of the immunologicalsynapse. The SH3 domain has been shown to be involved in membranerecruitment of CARD11 (67), and it is likely that membrane recruitmentof CARD11 is required for PKC ${theta}$ to act on the ID. However, itis not clear whether SH3-mediated membrane association or adistinct function of the SH3 domain is required for events downstreamof PKC ${theta}$ action. The PDZ-L3-SH3 region of CARD10 (also calledCARMA3) has been demonstrated in a yeast two-hybrid assay topresent a binding surface for IKK ${gamma}$ (56); however, our resultssuggest that these domains in CARD11 are not required for IKK ${gamma}$ association, which requires the coiled-coil domain and CARDinstead. The CARD11 GUK domain has been shown to bind PDK1 (27),a kinase that functions in this pathway in PKC ${theta}$ activation andin recruitment of CARD11 to lipid rafts in T cells. Since wedemonstrate a role for the GUK domain subsequent to ID neutralization,other GUK-binding proteins are likely to be involved in thispathway. Finally, the adhesion and degranulation-promoting adapterprotein (ADAP) has been shown to interact with the C-terminalhalf of CARD11 containing the PDZ, L3, SH3, L4, and GUK domains(33). Since ADAP is required for TCR signaling to NF- ${kappa}$ B, thisprotein may explain the requirement for one or more of theseCARD11 domains in this pathway in T cells. However, since ADAPis expressed in a tissue-restricted fashion and since L3, SH3,L4, and GUK domains function in both lymphoid and nonlymphoidcells, other proteins are likely to interact with these domainsduring CARD11-mediated signaling.

The integrative signaling function of CARD11 that is requiredfor normal antigen receptor signaling is also likely to playa critical role in the progression of some types of cancer.Lymphomas of mucosa-associated lymphoid tissue (MALT lymphoma)are associated with chromosomal translocations that lead tothe overexpression of Bcl10 or MALT1 or to the expression ofa hyperactive API2-MALT1 fusion protein (1, 12, 24, 31, 38,57, 64, 70, 72). It is possible that in MALT lymphoma the associationof these molecules with CARD11 is required for their dysregulatedsignaling to NF- ${kappa}$ B, which is thought to contribute to lymphomaprogression. The activated-B-cell-like subtype of diffuse largeB-cell lymphoma displays aberrant activation of the IKK complexand NF- ${kappa}$ B in a manner that is required for proliferation andsurvival (10, 26). Recently, CARD11 has been shown to be a requiredupstream signaling molecule in this lymphoma (42), and missensemutations in CARD11 have been found in $~$ 10% of activated-B-cell-likediffuse large B-cell lymphoma tumor biopsies (28). Intriguingly,several of these missense mutations increase the signaling abilityof CARD11 and map to the coiled-coil domain (28). Based uponour studies, we suggest that oncogenic coiled-coil mutationscould lead to enhanced signaling activity, most likely by disruptingthe inhibitory interaction that we have described between theID and the coiled-coil domain. Alternatively, one or more ofthese mutations could enhance the affinity of CARD11 for Bcl10,IKK ${gamma}$ , TRAF6, or caspase-8. Each of the surfaces that CARD11 usesto coordinate signaling to NF- ${kappa}$ B may provide a target for therapeuticamelioration of lymphomas that depend on CARD11 signaling. Importantly,since CARD11 appears to be critical in a limited number of NF- ${kappa}$ B-inducingpathways, pharmacological agents that target the scaffoldingfunction of CARD11 might not perturb the important biologicaleffects of the diverse array of physiological stimuli that regulateNF- ${kappa}$ B in other contexts.

ACKNOWLEDGMENTS

We thank V. Schowinsky for excellent technical assistance; M.Boldin, D. Baltimore, G. Nuñez, T. Kawai, S. Akira, andD. Goeddel for reagents; R. Lamason, S. Lew, V. Schowinsky,and J. McLellan for critical reading of the manuscript; andM. Meffert for helpful advice and discussions.

This work was supported by grant RSG-06-172-01-LIB from theAmerican Cancer Society and funds from the Johns Hopkins Institutefor Cell Engineering. J.L.P. is a recipient of a Kimmel ScholarAward from the Sidney Kimmel Foundation for Cancer Researchand a Rita Allen Foundation Scholar.

FOOTNOTES

* Corresponding author. Mailing address: Department of Biological Chemistry and Institute for Cell Engineering, The Johns Hopkins University School of Medicine, Broadway Research Building, Room 607, Baltimore, MD 21205. Phone: (443) 287-3100. Fax: (443) 287-3109. E-mail: joel.pomerantz{at}jhmi.edu

Published ahead of print on 14 July 2008.

Supplemental material for this article may be found at http://mcb.asm.org/.

REFERENCES

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