Address correspondence to John C. Reed, The Burnham Institute, 10901 North Torrey Pines Rd., La Jolla, CA 92037. Phone: 858-646-3140; Fax: 858-646-3194; E-mail: jreed{at}burnham.org
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Abstract |
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Key Words: inflammation signal transduction IB kinase monocytes NF-
B
Several DDF proteins are also known to participate in activation of transcription factor nuclear factor (NF)-
PAADs are found in diverse proteins implicated in apoptosis, inflammation, and cancer, though their molecular mechanisms of action are largely unknown. The founding member of the PAAD-family proteins, Pyrin, is mutated in families with Familial Mediterranean Fever, a hereditary hyperinflammatory response syndrome (10). Mutant alleles of a gene encoding another PAAD-family protein, Cryopyrin (PYPAF-1, NALP3) have been associated with familial cold auto-inflammatory syndrome, Muckle-Wells syndrome, and Chronic infantile neurological cutaneous and articular syndrome providing further hints of a role for PAADs in control of inflammatory responses (11, 12). A role for some PAAD-containing proteins in regulation of apoptosis has also been suggested (1316).
ASC consists of a NH2-terminal PAAD followed by a COOH-terminal CARD, representing one of only two genes in the human genome that encodes proteins combining these two protein interaction domains. ASC derives its name, "apoptosis-associated speck-like protein containing a CARD" from its reported ability to trigger apoptosis when overexpressed in some tumor cell lines and from its localization to punctuate cytosolic structures (specks; reference 15). ASC is also known as TMS1 (target of methylation-induced silencing), and becomes inactive in
RT-PCR.
Cell Culture, Transfection, and Reporter Gene Assays.
For NF-
Coimmunoprecipitations.
Kinase Assays.
NF-
Immunofluorescence Analysis.
Introduction
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
Proteins containing the death domain fold (DDF)* play pivotal roles in apoptosis and inflammatory responses. The DDF represents a protein interaction motif consisting of a bundle of (usually) six antiparallel -helices. This core structure comprises four families of evolutionarily conserved and closely related domain families, including the death domains (DDs), death effector domains (DEDs), caspase recruitment domains (CARDs), and Pyrin, AIM, Apoptosis-associated speck-like protein containing a Caspase recruitment domain (ASC), and death domain like (PAAD; also known as PYRIN, DAPIN, Pyk) domains (17).
B, a family of dimeric transcription factors containing the Rel-homology domain. In mammals, NF-
B family members play critical roles in regulating expression of genes involved in inflammatory and immune responses, including certain cytokines, lymphokines, immunoglobulins, and leukocyte adhesion proteins (for a review, see reference 8). NF-
Bs exist in the cytoplasm in inactive form sequestered by inhibitory proteins called inhibitor of NF-
B (I
B). Proteasome-dependent degradation of I
Bs is linked to their phosphorylation by the I
B kinase (IKK) complex, which consists of two related kinases, IKK
and IKKß, and a scaffold subunit IKK
(Nemo; for a review, see reference 9). Phosphorylation of I
Bs triggers their poly-ubiquitination and degradation, thus freeing NF-
B-family transcription factors to enter the nucleus and transactivate promoters of various target genes.
40% of breast cancers (16). Expression of ASC is found predominantly in monocytes and mucosal epithelial cells (17). Recently, it has been reported that, in transient transfection overexpression assays, coexpression of ASC with certain other PAAD-family proteins (Cryopyrin, PYPAF-7) activates NF-
B. However, the role of endogenous ASC has heretofore not been explored. We report here that the PAAD of ASC associates with the IKK complex, modulating activation of IKK
and IKKß by cytokines and LPS. Moreover, ASC has dual properties as either an enhancer or suppressor of NF-
B, depending on which pathways for NF-
B activation are stimulated.
Materials and Methods
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
Plasmids.
The complete open reading frame of ASC cDNA and segments corresponding to ASC-PAAD or -CARD were amplified by RT-PCR (Stratagene) from HL-60 cells and subcloned in sense and antisense orientation into pcDNA3 vector (Invitrogen) containing a NH2-terminal Myc epitope tag. Green fluorescent protein (GFP) fusion-protein vectors were generated by subcloning into pEGFP (CLONTECH Laboratories, Inc.). Authenticity of all constructs was confirmed by DNA sequencing. Plasmids encoding IKK, IKK
(K44M), IKKß, IKKß (K44A), and IKK
were gifts of Michael Karin (University of California, San Diego, CA), while IKKi, and TBK1 were gifts from Shizuo Akira (Osaka University, Osaka, Japan).
HEK293N Neo- or ASC-PAAD stable expressing cells were treated with 20 ng ml-1 TNF for 4 h, lysed in Trizol reagent (GIBCO BRL), and total RNA was isolated according to the instructions provided by the manufacturer. DNase Itreated RNA (1 µg) was transcribed into single-stranded cDNA using Superscript II (GIBCO BRL) and amplified for 30 cycles using Amplitaq (CLONTECH Laboratories, Inc.) with either TRAF1 or GAPDH specific primers.
HEK293N, HEK293T, and MCF7 cells were cultured in DMEM, while THP-1 cells were cultured in RPMI 1640 medium, supplemented with 10% heat-inactivated FBS. When indicated, cells were treated with 10 to 20 ng ml-1 TNF or IL-1ß, or 600 ng ml-1 LPS for various times. Transfection of HEK293 cells was accomplished using Superfect (QIAGEN), while THP-1 (107) cells were transfected with Lipofectamine Plus (Life Technologies), holding total DNA content constant. At 48 h after transfection, stable THP-1 cells or 293N cells were selected in 650 or 800 µg ml-1 G418 (Calbiochem), respectively. MCF7 and THP-1 cells were transfected with double-strand siRNAs on two consecutive days using Oligofectamine (Life Technologies). siRNA1: 5'-UCAUCCUGAAUCUGAUCUUdTdT-3', 5'-AAGAUCAGAUUCAGGAUGAdTdT-3', siRNA2: 5'-GAUGCGGAAGCUCUUCAGUdTdT-3', 5'-ACUGAAGAGCUUCCGCAUCdTdT-3', siRNAcntr: 5'-CAAGUAUUUGACGACCGAGdTdT-3', 5-CUCGGUCGUCAAAUACUUGdTdT-3'.
B reporter gene assays, typically, 105 cells cultured in 24-well plates in 5% serum were transfected with a total of 1 µg plasmid DNA (normalized for total DNA), including 100 ng of pNF-
B-LUC, pAP1-LUC, or p53-LUC (CLONTECH Laboratories, Inc.) and 6 ng of a Renilla luciferase gene driven by a constitutive TK promoter (pRL-TK; Promega). Lysates were analyzed using the Dual Luciferase kit (Promega).
For immunoprecipitations, cells were lysed in isotonic lysis buffer (150 or 500 mM NaCl, 20 mM Tris/HCl [pH 7.4], 0.2% NP-40, 12.5 mM ß-glycerophosphate, 2 mM NaF, 200 µM to 1 mM Na3VO4, 1 mM PMSF, and 1x protease inhibitor mix [Roche]), using 28 x 107 cells for endogenous proteins. Clarified lysates were subjected to immunoprecipitation using agarose-conjugated anti-c-Myc (Santa Cruz Biotechnology, Inc.), or protein-Gconjugated anti-IKKß (Santa Cruz Biotechnology, Inc.), anti-IKK (BD Biosciences), or anti-ASC antibodies (17). After incubation at 4°C for 412 h, immune-complexes were washed three times in lysis buffer, separated by SDS/PAGE, and analyzed by immunoblotting using various antibodies as above in conjunction with ECL detection system (Amersham Biosciences). Alternatively, lysates were directly analyzed by immunoblotting after normalization for total protein content. Anti-Tubulin and anti-ß-Actin antibodies were purchased from Sigma-Aldrich, and antiICAM-1 and anti-GFP antibodies were purchased from Santa Cruz Biotechnology, Inc.
IKK or IKKß were immunoprecipitated from cell lysates, using 5 x 105 cells for IKK transfectants and 106 cells for endogenous IKKs. Immune-complexes were washed twice in lysis buffer (as above), once in lysis buffer containing 2 M urea followed by two washes in kinase buffer (20 mM Hepes [pH 7.6], 50 mM NaCl, 20 mM ß-glycerophosphate, 1 mM Na3VO4, 0.5 mM DTT), equilibrated for 5 min in kinase buffer, adjusted to 10 mM MgCl2 and 1 mM DTT, and finally incubated in 20 µl kinase buffer supplemented with 35 µM ATP, 5 µCi
[32P] ATP and 1 µg glutathionine-S-transferase (GST)-I
B
(Santa Cruz Biotechnology, Inc.) at 30°C for 30 min (18).
B DNA-binding Activity Assays.
Electromobility gel-shift assays (EMSA) were used to measure NF-B DNA-binding activity, essentially as described (19). Briefly, 106 cells, either untreated or treated with TNF
for 20 min were lysed in buffer A (10 mM Hepes, pH 8.0, 0.5% NP-40, 1.5 mM MgCl2, 10 mM KCl, 0.5 mM DTT, and 200 mM sucrose), washed twice in buffer A, and pelleted nuclei were incubated in 1x packed cell volume of buffer B (20 mM Hepes, pH 7.9, 1.5 mM MgCl2, 420 mM NaCl, 0.2 mM EDTA, and 1 mM DTT) overnight, clarified supernatants diluted 1:1 in buffer C (20 mM Hepes, pH 7.9, 100 mM KCl, 0.2 mM EDTA, 20% glycerol, and 1 mM DTT). Protease and phosphatase inhibitors were added to all buffers. Nuclear extracts (2 µg) were incubated with 10 fmole of a 32P-end-labeled double-strand consensus NF-
B oligonucleotide (Promega) probe with or without 2 µg of anti-p65 antibody or control IgG (Santa Cruz Biotechnology, Inc.). For competition assays, a 50x molar excess of unlabeled oligonucleotide was added. DNAprotein complexes were separated by nondenaturing PAGE, and analyzed by autoradiography.
Cells were transferred to 4-well polylysine-coated chamber slides (LabTec), fixed in 4% paraformaldehyde, stained with 0.4 µg ml-1 of the indicated antibodies (Santa Cruz Biotechnology, Inc.), followed by 4 µg ml-1 FITC and TRITC labeled secondary antibodies (DakoCytomation/Molecular Probes). Both secondary antibodies were combined and used for each well in 0.1% BSA and 1% serum. Cells were analyzed by confocal laser-scanning microscopy (Bio-Rad Laboratories).
Results
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
ASC Differentially Modulates NF-B Activity, Depending on the Stimulus.
Recently, it was reported that coexpression of ASC with Cryopyrin (PYPAF-1/NALP3) or PYPAF-7 (PAN6) induces NF-B activity in transient transfection reporter gene assays performed in HEK293T cells (20, 21). These cells contain essentially no detectable ASC (unpublished data), thus avoiding contributions of the endogenous ASC protein. Similar to previous reports, we observed 2070-fold inductions in NF-
B activity, when ASC was coexpressed with Cryopyrin or Pyrin in HEK293T cells, as measured by reporter gene assays in HEK293T cells (Fig. 1 A). In contrast, neither ASC, nor Pyrin or Cryopyrin alone induced significant NF-
B activity. The ability of ASC to collaborate with other PAAD-containing proteins in NF-
B induction was selective, as coexpression with NAC (NALP1, DEFCAP, CARD7), PAN1 (PYPAF-2, NALP2, NBS1), or PAN2 (PYPAF-4, NALP4) did not result in significant NF-
B activity.
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To extend these studies to other types of stimuli known to induce NF-B activity, we performed similar reporter gene assays, stimulating cells with the cytokine IL-1ß or transfecting cells with NF-
Binducing proteins such as Bcl-10 (which has been implicated in NF-
B induction by B cell and T cell antigen receptors; reference 22) and Nod-1 (a putative intracellular sensor of LPS; reference 23). In every case examined, transient overexpression of ASC suppressed NF-
B activity (Fig. 1, CE). Similar results were obtained for several cell lines, including HEK293T, HEK293N, HeLa, Cos7, and HT1080 cells (unpublished data). The effects of ASC on NF-
B induction were specific, in as much as overexpression of ASC did not interfere with transcriptional activation of p53, AP-1, ß-Catenin/Tcf, as measured by reporter gene assays (Fig. 1, F and G; and unpublished data). Immunoblotting experiments confirmed production of all plasmid-derived proteins, excluding a general effect of ASC on protein synthesis or stability (see below).
ASC Inhibits NF-B Induction via Its PAAD.
To map the domain in ASC responsible for modulation of NF-B activity, we compared the effects of full-length ASC to truncation mutants containing only the PAAD or CARD domains. Neither the PAAD nor the CARD of ASC induced NF-
B activity when expressed by transient transfection in cell lines such as HEK293N (Fig. 2 A), consistent with a previous report (24). In TNF
-stimulated cells, both full-length ASC and the PAAD of ASC profoundly suppressed NF-
B activity, while the CARD of ASC did not (Fig. 2 B). Inhibition of TNF
-induced NF-
B activity by the PAAD of ASC was dose-dependent (Fig. 2 C). NF-
B DNA binding activity was also reduced by overexpression of the PAAD of ASC, as measured by EMSAs using a DNA probe containing NF-
B binding sites (Fig. 2 D), and correlated with reduced translocation of the p65 subunit of NF-
B into the nuclei of TNF
-stimulated cells, as visualized by immunofluorescence microscopy analysis (unpublished data).
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Next, we evaluated whether stable expression of ASC-PAAD interfered with TNF-induced expression of an endogenous NF-
B target gene, TRAF1, which contains several NF-
B binding sites in its promoter (25). While TNF
increased TRAF1 protein and mRNA, this response was markedly blunted in ASC-PAADexpressing cells (Fig. 2, G and H). Analysis of control proteins (TRAF2, Tubulin) and control mRNA (GAPDH) demonstrated the specificity of these results.
To extend these studies yet to another cell line, THP-1 monocytic cells were stably transfected with plasmids encoding either GFP or GFP fused to ASC-PAAD. LPS induced expression of endogenous NF-Binducible gene, ICAM-1 (26), in control GFP-expressing THP-1 cells, producing a >20-fold increase in ICAM-1 protein within 10 h (Fig. 2 I). In contrast, ICAM-1 was markedly reduced in ASC-PAADexpressing cells. Comparable expression of GFP-ASC-PAAD and GFP was confirmed by immunoblotting with anti-GFP antibody (Fig. 2 I). Taken together, these data indicate that ASC is capable of suppressing TNF
- and LPS-induced expression of endogenous NF-
B target genes through its PAAD.
ASC-PAAD Modulates NF-B Induction at the Level of the IKK Complex.
To map where the PAAD of ASC affects the NF-B activation pathway, NF-
B activity was induced by transient transfection of plasmids encoding various intracellular signal-transducers that operate within cytokine receptor pathways leading to phosphorylation of I
B, a key event required for NF-
B release. Coexpression of ASC blocked induction of NF-
B activity by the adaptor proteins TRAF2 and TRAF6, the TRAF-binding kinases TBK1 and NIK, the IKK complex constituents IKK
and IKKß, and the related kinase IKKi (Fig. 3 A). In contrast, coexpression of ASC did not suppress reporter gene activation induced by NF-
B-p65. Thus, ASC blocks upstream of NF-
B, apparently at the level of the IKK complex.
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To extend these studies involving expression of epitope-tagged proteins by transient transfection, the activity of endogenous IKK was evaluated using HEK293N cells stably transfected with either control or Myc-ASC-PAAD (Fig. 3 E). ASC-PAAD potently suppressed TNF
-induced activation of endogenous IKK
in these cells, as determined by kinase assays where immunoprecipitated IKK
was tested for ability to phosphorylate GST-I
B
substrate in vitro. Autophosphorylation of IKK
was also suppressed in ASC-PAADexpressing cells. These differences in IKK
activity were not due to differences in the total levels of IKK
protein, as determined by immunoblotting (Fig. 3 E).
ASC Associates with IKK and IKKß.
Having mapped the site of action of ASC to the IKK complex, we performed experiments to explore whether ASC associated with these protein kinases. In the course of our studies of ASC, we observed that expression of ASC is induced in myeloid-lineage hematopoietic cells such as THP-1 monocytic or HL-60 monomyelocytic leukemia cell lines by LPS and TNF (Fig. 2 E, and unpublished data). We therefore asked whether endogenous ASC protein could be found associated with endogenous IKK complex components after LPS- or TNF
-stimulation in these cells. Co-IP experiments provided evidence of association of ASC with both IKK
and IKKß in LPS-stimulated THP-1 and TNF
-treated HL-60 cells (Fig. 4 A, and unpublished data). These protein interactions were reciprocally demonstrable, regardless of whether immune-complexes were prepared using anti-IKK
and anti-IKKß antibodies (followed by immunoblotting with anti-ASC antiserum) or using anti-ASC antiserum (followed by immunoblotting with anti-IKK
or anti-IKKß antibodies; Fig. 4 A, and unpublished data). We also analyzed the HEK293N-ASC-PAAD stable transfectants to determine whether the PAAD is sufficient for association with the endogenous IKK complex. Again, coimmunoprecipitation (coIP) experiments demonstrated specific interaction of ASC-PAAD with the endogenous IKK complex, as indicated by the association of ASC with IKK
, IKKß, as well as IKK
(Fig. 4 B).
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Suppression of Endogenous ASC Expression Enhances IB
Degradation.
As IKK activity induces phosphorylation and subsequent degradation of IB-family proteins, we evaluated the effects of the PAAD of ASC on levels of endogenous I
B
in these stably transfected cells, before and at various times after TNF
stimulation. Immunoblot analysis of lysates from HEK293N-Neo cells using anti-I
B
antibody demonstrated the appearance of a doublet band (indicative of phosphorylation of I
B
) within 5 min after TNF
simulation, followed by disappearance of I
B
protein. In contrast, I
B
protein levels were sustained at detectable levels in ASC-PAADexpressing HEK293N cells despite TNF
treatment. Furthermore, the I
B
doublet band indicative of phosphorylation was not observed until much later, at 1530 min after stimulation (Fig. 5 A), thus demonstrating a marked delay relative to control cells.
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Discussion |
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We propose therefore that ASC is a dual modulator of NF-B activation, which by virtue of its association with IKKs, acts at a point of convergence of multiple pathways leading to NF-
B induction. The ability of ASC to either enhance or inhibit NF-
B induction, depending presumably on the ratio of its levels relative to other ASC-binding proteins, is reminiscent of proteins such as c-FLIPL, which can function as either a pro-Caspase-8 activator or inhibitor, dependent on cell context (32). Similarly, some IAP-family proteins can either enhance or inhibit NF-
B induction by TNF
, depending apparently on whether they induce degradation of certain associated proteins (33, 34), but a combination of both stimulatory and inhibitory properties has not been attributed thus far to a single protein (e.g., cIAP1 inhibits; cIAP2 enhances). Thus, ASC may represent the first identified protein that has dual properties as both an inhibitor and enhancer of NF-
B induction. Though other interpretations are possible, this two-sided nature of ASC is entirely consistent with its hypothesized role as a molecular bridge involved in assembly of multiprotein complexes (molecular machines), in which the correct stoichiometry of components would be necessary for activity and where either insufficiency or excess of ASC could interfere with complex assembly.
Evidence is presented here that ASC associates with components of the IKK complex, the kinase complex responsible for phosphorylation of the IB family proteins that sequester NF-
B in the cytosol (for a review, see reference 35). In pilot experiments, we could not demonstrate interaction of ASC with constituents of the IKK complex by ectopic overexpression of ASC with epitope-tagged IKK
, IKKß, or IKK
individually, as determined by coIP experiments (unpublished data). Thus, we favor the idea that ASC associates directly or indirectly with the assembled IKK complex. However, ectopic overexpression of single components of the IKK complex might disrupt the complex because of changes in protein stoichometry, thus preventing ASC binding. Interestingly, Chen et al. recently demonstrated the existence of several additional proteins associated with endogenous IKK complexes (36). It remains to be determined whether ASC associates with IKK complexes through one of these proteins. Also, the molecular events that govern physical and functional interactions of ASC with the IKK complex remain to be clarified, including the possible role of posttranslational modifications of ASC or other associated proteins. Thus, it is unclear at present how the PAAD of ASC suppresses IKK activation in response to proinflammatory stimuli.
Recently, we determined that another PAAD-family protein, PAN2, can also associate with IKK and suppress IKK
activation by TNF
(19). Interestingly, however, PAN2 does not appear to associate with IKKß or IKK
, suggesting the possibility of differences in interactions with IKK complex components compared with ASC, which could be coimmunoprecipitated with either anti-IKK
or anti-IKKß antibodies. Similar to ASC, however, the PAAD of PAN2 is sufficient for interactions with and suppression of IKK
(19).
Though we used the PAAD domain of ASC as a probe to demonstrate the ability of this region of ASC to functionally and physically interact with IKK complex components, it should be noted that the human genome contains at least two genes predicted to encode PAAD-only proteins (reference 3, and unpublished data), which are analogous to the ASC-PAAD protein employed here in our studies. Furthermore, we have observed that these proteins function very similar to the PAAD of ASC in their effects on IKK and NF-B induction (unpublished data). Some poxviruses also contain potential ORFs encoding proteins with significant sequence similarity to cellular PAADs, such as the rabbit myxoma virus. Thus, endogenous and viral proteins consisting of only the PAAD domain may operate as negative regulators of IKK activation, analogous to our studies of a fragment of ASC comprising only the PAAD domain. Just as the mechanism by which ASC suppresses IKK activation induced by proinflammatory stimuli is presently unknown, similarly, it remains unclear how ASC enhances NF-
B induction when coexpressed with PAAD-family proteins such as Pyrin, (this paper), Cyropyrin (20), and PYPAF-7 (21). ASC has been reported to recruit Pyrin, Cryopyrin, and PYPAF-7 into cytosolic specks (20, 21, 28), suggesting a role for these intracellular bodies in the process of NF-
B induction, but the location of IKK complex proteins under these circumstances has not been assessed. Future studies should therefore address the consequences of Pyrin, Cryopyrin, and PYPAF-7 protein interactions with ASC with regards to association with and regulation of the IKK complex.
Interestingly, ASC associates with uncharacterized structures in the cytosol of cells, forming specks. The formation of speck-like structures is not merely an artifact of protein overexpression, because they can be identified by immunohistochemical techniques in normal tissue (17), and because certain treatments of cultured cells can induce speck formation by endogenous ASC (15). Indeed, the endogenous ASC protein was first discovered because of its association with Triton X-100insoluble aggregates in HL-60 cells pretreated with retinoic acid (15). The targeting of ASC to these locations requires the combination of PAAD and CARD (unpublished data), and truncation mutants of ASC containing only the PAAD form filament-like structures in the cytosol of cells, but fail to produce the speck-like morphology for which this protein was named. In ASC-PAADexpressing cells, IKK components colocalized with these filaments, which form in a manner reminiscent of previously identified NF-B regulators, such as TRADD, RIP, and Bcl-10 (37, 38). Given recent suggestions that the ASC-binding protein Pyrin associates with cytoskeletal proteins, it is tempting to speculate the ASC may associate with or coordinate formation of a specialized site on the cytoskeleton (39). The fate of proteins recruited to these uncharacterized complexes where ASC localizes is unknown. We have seen no evidence that ASC overexpression results in degradation of ASC-interacting proteins. Possibly speck-like structures targeted by ASC are sites for posttranslation protein modifications or simply providing a location for sequestering certain proteins.
ASC was originally reported to induce apoptosis when overexpressed in certain tumor lines (15, 24). However, at the doses of ASC-encoding plasmid employed and levels of ASC expression attained in our experiments, we did not observe apoptosis. Based on our findings, we propose that ASC might modulate apoptosis under some circumstances where NF-B is important for avoiding cell death, given that NF-
B can regulate expression of apoptosis-relevant genes such as A20, Bcl-XL, Bfl-1, cIAP2, and others (for a review, see reference 40). In this regard, inhibition of IKKs is known to sensitize cells to apoptosis induction by TNF-family death ligands (41). These effects of ASC on apoptosis might account for the observation that this gene is commonly silenced in breast cancers by gene methylation (16).
Because expression of ASC is initially low but inducible by LPS and TNF in THP-1 monocytic cells, we speculate that ASC may be involved in a negative feedback suppression of pathways that induce NF-
B. This inducible expression in response to a variety of proinflammatory stimuli was also recently demonstrated in neutrophils (42). In this way, ASC could play a role in terminating inflammatory responses, thus ensuring that only a short burst of NF-
B activity activation occurs. This scenario is consistent with our siRNA results where reductions in ASC were correlated with enhanced I
B
degradation. An alternative but not mutually exclusive possibility is that antagonism of the TNF
, IL-1ß, and LPS pathways for NF-
B induction by ASC reflects a competition between alternative pathways for access to IKK or IKK-associated proteins. In this regard, the physiological or pathogenic stimuli that normally engage ASC and other PAAD-family proteins in NF-
B induction are unknown, but at least 14 members of the PAAD family have been identified that contain leucine rich repeats (LRRs) similar to those found in the extracellular domains of Toll-related receptors (TLRs) and in the CARD-family proteins Nod1 and Nod2, which are known to bind bacterial LPS or other molecules made by microbial pathogens. Thus, while speculative, many PAAD-family proteins may participate in a pathway that senses intracellular bacteria. Cross talk between this pathway and other NF-
B activation pathways, such as those triggered by TNF
, IL-1ß, TLRs, and antigen receptors (TCR, BCR), may play important roles in steering innate and acquired immune responses toward different ultimate outcomes. Future studies, including targeted ablation of the gene encoding ASC in mice, will reveal the overall importance of ASC in inflammation and innate immunity.
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Acknowledgments |
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C. Stehlik and L. Fiorentino are recipients of fellowships from the Austrian Science Foundation (FWF, J1809-Gen/J1990-Gen), Department of Defense (DOD) Breast Cancer Research Program (DAMD17-01-1-0171), and the American-Italian Cancer Foundation, respectively.
Submitted: September 3, 2002
Revised: October 22, 2002
Accepted: November 4, 2002
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Footnotes |
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* Abbreviations used in this paper: ASC, apoptosis-associated speck-like protein containing a Caspase recruitment domain; coIP, coimmunoprecipitation; CARD, Caspase-recruitment domain; DDF, death domain fold; EMSA, electromobility gel-shift assays; GFP, green fluorescent protein, GST, glutathionine-S-transferase; I
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