A Lipopolysaccharide-Specific Enhancer Complex Involving Ets, Elk-1, Sp1, and CREB Binding Protein and p300 Is Recruited to the Tumor Necrosis Factor Alpha Promoter In Vivo

doi:10.1128/MCB.20.16.6084-6094.2000

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Molecular and Cellular Biology, August 2000, p. 6084-6094, Vol. 20, No. 16
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

A Lipopolysaccharide-Specific Enhancer Complex Involving Ets, Elk-1, Sp1, and CREB Binding Protein and p300 Is Recruited to the Tumor Necrosis Factor Alpha Promoter In Vivo

Eunice Y. Tsai,¹ James V. Falvo,² Alla V. Tsytsykova,¹ Amy K. Barczak,¹ Andreas M. Reimold,³ Laurie H. Glimcher,³ Matthew J. Fenton,⁴ David C. Gordon,¹ Ian F. Dunn,¹ and Anne E. Goldfeld¹^,^*

The Center for Blood Research and Harvard Medical School¹ and The Harvard School of Public Health,³ Boston, Massachusetts 02115; Department of Molecular and Cellular Biology, Harvard University, Cambridge, Massachusetts 02138²; and Pulmonary Center, Boston University School of Medicine, Boston, Massachusetts 02118⁴

Received 10 May 2000/Accepted 19 May 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The tumor necrosis factor alpha (TNF- $alpha$ ) gene is rapidly activated by lipopolysaccharide (LPS). Here, we show that extracellularsignal-regulated kinase (ERK) kinase activity but not calcineurinphosphatase activity is required for LPS-stimulated TNF- $alpha$ geneexpression. In LPS-stimulated macrophages, the ERK substratesEts and Elk-1 bind to the TNF- $alpha$ promoter in vivo. Strikingly,Ets and Elk-1 bind to two TNF- $alpha$ nuclear factor of activated Tcells (NFAT)-binding sites, which are required for calcineurinand NFAT-dependent TNF- $alpha$ gene expression in lymphocytes. The transcriptionfactors ATF-2, c-jun, Egr-1, and Sp1 are also inducibly recruitedto the TNF- $alpha$ promoter in vivo, and the binding sites for eachof these activators are required for LPS-stimulated TNF- $alpha$ geneexpression. Furthermore, assembly of the LPS-stimulated TNF- $alpha$ enhancer complex is dependent upon the coactivator proteins CREBbinding protein and p300. The finding that a distinct set of transcriptionfactors associates with a fixed set of binding sites on the TNF- $alpha$ promoter in response to LPS stimulation lends new insights intothe mechanisms by which complex patterns of gene regulation areachieved.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Tumor necrosis factor alpha (TNF- $alpha$ ) is a proinflammatory cytokine that activates multiple-signal transduction pathways andinfluences a broad range of immunological processes. Multipleextracellular stimuli induce the synthesis of TNF- $alpha$ in a widevariety of cell types, including T and B cells, monocytes andmacrophages, mast cells, and fibroblasts (reviewed in reference1). We have shown that induction of TNF- $alpha$ gene transcriptionby T or B cell receptor engagement, virus infection, and treatmentwith a calcium ionophore depends upon the activity of the phosphatasecalcineurin (15, 18, 20). Calcineurin targets the nuclearfactor of activated T cells (NFAT) family of proteins (reviewedin references 11 and 38), which are critical for TNF- $alpha$ geneexpression by calcineurin-dependent signal transduction pathways(15, 48, 49).

Production of TNF- $alpha$ in response to lipopolysaccharide (LPS), a component of the cell wall of gram-negative bacteria, is ofparticular clinical importance because TNF- $alpha$ is a mediator ofseptic shock (reviewed in reference 1). Exposure of monocytesand macrophages to LPS results in activation of the mitogen-activatedprotein kinase (MAPK) pathway, including the extracellular signal-relatedkinase (ERK), c-jun NH₂-terminal kinase (JNK), and p38 cascades(reviewed in reference 12).

Here, we show that ERK, but not calcineurin or p38, is required for full transcriptional induction of TNF- $alpha$ gene expressionby LPS. We identify TNF- $alpha$ promoter elements critical for LPS inductionof the gene and demonstrate that two Sp1 binding sites and threeEts binding sites, in addition to a cyclic AMP response element(CRE)-like site and an Egr site, are critical for LPS inductionof the TNF- $alpha$ gene. Consistent with this functional analysis ofthe TNF- $alpha$ promoter, using chromatin immunoprecipitation and formaldehydecrosslinking (ChIP) assays, we directly detect LPS-inducible bindingof the transcription factors ATF-2, c-jun, Ets-1 and -2, Elk-1,Egr-1, and Sp1 to the endogenous TNF- $alpha$ promoter. Furthermore,we show that LPS-mediated TNF- $alpha$ transcription is dependent uponCREB binding protein (CBP) and p300 coactivator proteins and,moreover, that the intrinsic transcriptional activity of CBP andp300 is potentiated byLPS.

Thus, a unique TNF- $alpha$ enhancer complex, including Ets, Elk-1, Sp1, ATF-2-Jun, and the coactivator proteins CBP and p300, isassembled on the TNF- $alpha$ promoter in LPS-stimulated monocytes. Remarkably,a set of TNF- $alpha$ promoter elements, which bind NFAT upon inductionof the gene by calcineurin-dependent stimuli, also bind the ERK-targetedEts and Elk proteins and are required in LPS-stimulated TNF- $alpha$ gene expression. Thus, these studies reveal that a distinct groupof activators is recruited to a fixed set of TNF- $alpha$ promoter bindingsites, depending on the stimulus. This work therefore providesdirect evidence for a general mechanism by which a single genemay be regulated in an inducer-specificmanner.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Cell culture and transfection. J774 (49), P388D1 (17), Mono Mac-6 (60), and ANA-1 cells (10) were maintained as previously described. Transfectionsin J774, ANA-1, and Mono Mac-6 cells were performed using FuGene6(Boehringer-Mannheim) according to the manufacturer's protocol.Transfections in RAW264.7 cells were performed using Super-Fect(Qiagen) as described previously (35). Thirty-six hours aftertransfection, cells were treated with LPS (Sigma; Escherichiacoli O111:B4) at a concentration of 1 µg/ml and harvested approximately16 h later. Chloramphenicol acetyltransferase (CAT) assays wereperformed as previously described (18). As a transfection control,the pCMV $beta$ plasmid (Clontech) was cotransfected and extracts werenormalized to $beta$ -galactosidase ( $beta$ -Gal) activity prior to performanceof CAT assays. Luciferase assays were performed according to themanufacturer's instructions (Dual Luciferase Reporter Assay System;Promega) using a Dynex luminometer, with Renilla luciferase (pRL-TK)as acontrol.

RNA analysis. RNA was prepared from J774, P388D1, and Mono Mac-6 cells, or splenocytes from ATF-2 mutant mice or NFATp-deficient mice, and³²P-labeled RNA probes were prepared from SP6 $gamma$ -actin and murineTNF- $alpha$ probes. RNase protection assays were performed as previouslydescribed (18) and quantified with a phosphorimager (MolecularDynamics). The ATF-2 mutant mice (40) contain low levels ofa mutant ATF-2 protein; ATF-2-deficient mice die immediately afterbirth (33) and are thus not suitable for in vivo LPS experiments.ATF-2 mutant mice and wild-type littermates were injected with50 µg of LPS, and RNA was prepared from whole spleens as previouslydescribed (40). Spleens were removed from mice deficient inNFATp (23) and stimulated in vitro with LPS (1 µg/ml) for 1h as described (17). Where indicated, cells were pretreatedfor 10 min with cyclosporin A (CsA) (Sandoz), SB203580 (a giftfrom Genetics Institute, synthesized based on a published procedure)(5), or PD98059 (BioMol Research Labs) at the concentrationsindicated in the figurelegends.

Plasmids. The $-$ 200 TNF- $alpha$ CAT, $-$ 1045 TNF- $alpha$ CAT, $-$ 200 TNF- $alpha$ Luc, $-$ 39 TNF- $alpha$ CAT, (CRE/ $kappa$ 3)¹ $-$ 39 TNF- $alpha$ CAT, (CRE/ $kappa$ 3)² $-$ 39 TNF- $alpha$ CAT, and (CRE/ $kappa$ 3)² $-$ 39 TNF- $alpha$ Luc constructs have been described previously (6,17, 21, 48). The $-$ 982 TNF- $alpha$ Luc reporter was created bysubcloning the SmaI-HincII fragment of $-$ 982 TNF- $alpha$ CAT (50) intothe SmaI site of pGL3-Basic (Promega, Madison, Wis.). The (C1M)² $-$ 39 TNF- $alpha$ Luc and (3'M)² $-$ 39 TNF- $alpha$ Luc reporters were created by subcloning the SmaI-HincIIfragment of the (C1M)² $-$ 39 TNF- $alpha$ CAT and (3'M)² $-$ 39 TNF- $alpha$ CAT reporters (48) into the SmaI site of pGL3-Basic.The $-$ 117M, $-$ 113M, C1M, $kappa$ 3 5' M, $kappa$ 3 3'M, $-$ 76M, AP1M, and SP1M luciferasereporters were created by subcloning the BamHI-XbaI fragment ofthe corresponding CAT constructs (18, 48, 49) into pBluescript(Stratagene) and subcloning the KpnI-XbaI fragment of the resultingvector into the KpnI-NheI sites of pGL3-Basic. The $-$ 84M CAT reporterfrom which the $-$ 84M luciferase reporter was created was constructedby M13 in vitro mutagenesis as described (49). The Up-Sp1M,EgrM, and Egr/Up-Sp1M luciferase reporters were prepared by standardPCR mutagenesis. All mutations were confirmed by sequencing. TheG5E1b-Luc reporter and the Gal4-p300 vector have been describedelsewhere (14, 59). The Gal4-CBP expression vector was a generousgift of D. Thanos (ColumbiaUniversity).

DNase I footprinting. DNase I footprinting of the human TNF- $alpha$ promoter was performed using recombinant NFATp, Ets-1, Elk-1, and PU.1 proteins (generousgifts of D. Thanos, B. Nikolajczyk, A. Sharrocks, and H. Singh,respectively) at concentrations indicated in the figure legends,as described previously (49). The $-$ 200 to +87 fragment of thewild-type TNF- $alpha$ promoter or isogenic constructs bearing the $-$ 76M, $-$ 84M, $kappa$ 3 3'M, $-$ 113M, and $-$ 117M mutations as shown in Fig. 7 wereused astemplates.

Western blot analysis. For Western blot analysis, after nuclear extract preparation (18), equal amounts of protein (30 µg/sample) were analyzedby sodium dodecyl sulfate-10% polyacrylamide gel electrophoresis,transferred on nitrocellulose membranes and immunoblotted withanti-ERK1 and anti-ERK2 (anti-ERK1/2) antibody (Upstate Biotechnology,Lake Placid, N.Y.) or anti-phospho-ERK1/2 (anti-phospho-p44 or-p42 MAPK [Thr202-Tyr204]) antibody (New England Biolabs). Immunodetectionwas performed by incubation with horseradish peroxidase-conjugatedanti-mouse immunoglobulin G (Promega) and developed by chemiluminescence(New England Nuclear, Boston, Mass.).

Formaldehyde crosslinking and chromatin immunoprecipitation. J774 cells (~2 × 10⁸ cells) and control samples were treated with LPS for 3 h as indicated and then were treated with formaldehyde(1% final concentration) for 30 min at 37°C. Cells were harvested,and fixed chromatin was sonicated, extracted, and purified, followedby immunoprecipitation with anti-c-jun, anti-ATF-2, anti-Sp1,anti-Egr-1, anti-Ets-1 and -2, anti-Elk-1, or anti-C/EBP $beta$ (SantaCruz Biotechnology). Immunoprecipitated DNA was then amplifiedby PCR with primers specific to the TNF- $alpha$ promoter as previouslydescribed (15). Titrations of PCR cycles were performed to ensurethat experiments were performed in the linear range ofamplification.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

The region from nucleotide (nt) $-$ 200 to the TNF- $alpha$ transcription start site is sufficient for maximal LPS inducibility of TNF- $alpha$ . We first compared LPS induction of the endogenous TNF- $alpha$ gene in murine (J774, P388D1) and human (Mono Mac-6) monocytic celllines stimulated with LPS to determine an appropriate system inwhich to study LPS-stimulated TNF- $alpha$ gene expression. As shownin Fig. 1, TNF- $alpha$ mRNA was highly inducible by LPS in all threecell lines; however, relatively higher levels of inducible TNF- $alpha$ mRNA were achieved in the J774 cells than in the P388D1 and MonoMac-6 cells (Fig. 1).

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FIG. 1. Induction of TNF- $alpha$ mRNA by LPS in monocytic cell lines. Autoradiograms are shown of RNase protection assays mapping TNF- $alpha$ and $gamma$ -actin mRNAs from untreated or LPS-stimulated J774 (lanes 1 to 3), P388D1 (lanes 4 to 6), and Mono Mac-6 (lanes 7 to 9). RNA was analyzed at 1 or 4 h poststimulation as indicated.

The region from nt $-$ 200 to the human TNF- $alpha$ mRNA cap site is sufficient for maximal induction of the TNF- $alpha$ gene by LPS in murineP388D1 cells (17), THP-1 human monocytic cells (47, 58),and murine RAW264.7 monocytic cells (22). As shown in Fig. 2A,deletion of the sequences between nt $-$ 1045 and $-$ 200 had no effecton LPS induction of the TNF- $alpha$ CAT reporter gene, and thus thisregion is also sufficient for maximal induction of the TNF- $alpha$ geneby LPS in J774 cells.

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FIG. 2. The region from nt $-$ 200 upstream of the TNF- $alpha$ mRNA cap site suffices for LPS induction. J774 (A) and ANA-1 (B) cells were transfected with 2 µg of CAT (A) or luciferase (B) reporters linked to human TNF- $alpha$ promoters containing $-$ 200 and $-$ 1045 (CAT) or $-$ 200 and $-$ 982 (luciferase) nucleotides upstream of the mRNA cap site and treated with LPS as shown. (A) A representative CAT assay of three independent transfections is shown. Transfections included 2 µg of pCMV $beta$ as a control, and CAT activity was normalized to $beta$ -Gal activity. (B) Histograms of luciferase activity from five independent experiments are shown; error bars indicate standard errors of the means. All transfections included a control Renilla luciferase plasmid (2 µg), and reporter luciferase activity was normalized to Renilla luciferase activity.

A recent report claimed that sequences around nt $-$ 600 relative to the human TNF- $alpha$ mRNA cap site that contain a strong NF- $kappa$ Bbinding motif, $kappa$ 1 (17, 47), were required for maximal expressionof the TNF- $alpha$ gene in murine ANA-1 and human Mono Mac-6 cells (27).Thus, to rule out a cell-type-specific difference in TNF- $alpha$ generegulation by LPS, we also transfected the ANA-1, Mono Mac-6 celllines and RAW264.7 cells with TNF- $alpha$ luciferase reporter genescontaining nt $-$ 982 or $-$ 200 upstream of the TNF- $alpha$ transcriptionstart site. We found that there were only minimal differencesin induction between the nt $-$ 200 and $-$ 982 luciferase reporterconstructs in ANA-1 (Fig. 2B), Mono Mac-6 cells, and RAW264.7(data not shown), in agreement with results obtained with J774,THP-1, and P388D1 cells. Thus, consistent with experiments performedwith multiple cell types, including monocytes, T, B, and fibroblastcells stimulated with a variety of inducers (6, 17-19, 22,47, 48, 58), the region from nt $-$ 200 upstream of the startsite of transcription contained the critical sequences requiredfor inducibility of the TNF- $alpha$ gene. We are unable to explain thediscrepancy between our findings and those previously reportedfor ANA-1 and Mono Mac-6 cells (27).

The CRE, Sp1, Ets-Elk, and Egr sites are required for LPS induction of TNF- $alpha$ gene expression. To identify the promoter elements required for LPS induction of the TNF- $alpha$ gene, we transfected J774 cells with human TNF- $alpha$ luciferase reporter constructs bearing mutations in differentregulatory elements. Mutation of the $-$ 117-NFAT ( $-$ 117M), CRE (C1M), $kappa$ 3-NFAT (5'M and 3'M), $-$ 76-NFAT ( $-$ 76M), and Sp1 (SP1M) sites,as well as sequences that match an Ets-Elk-1 motif located betweennt $-$ 84 and $-$ 80 ( $-$ 84M), significantly reduced LPS induction ofthe gene (Fig. 3A). It should be noted that both the C1M and $kappa$ 35'M mutants inhibit binding of ATF-2/c-jun to the TNF- $alpha$ promoter(48, 49). By contrast, mutation of a putative AP-1 site (AP1M)had no effect on LPS induction of the gene expression. Mutationof this site, which bears limited sequence similarity to a consensusAP-1 site, also had no effect on the regulation of the gene byLPS in THP-1 cells (58) and by a variety of inducers in multiplecell types (6, 15, 21, 48).

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FIG. 3. Identification of activator binding sites required for LPS induction of TNF- $alpha$ . (A) The CRE, Sp1, and Ets-NFAT sites are required for LPS induction of TNF- $alpha$ . J774 cells were transfected with 2 µg of the wild-type $-$ 200 TNF- $alpha$ luciferase reporter or with isogenic reporters containing mutations in the $-$ 117 NFAT ( $-$ 117M), CRE (C1M), $kappa$ 3-NFAT (5'M and 3'M), Ets-Elk ( $-$ 84M), $-$ 76-NFAT ( $-$ 76M), Sp1 (SP1M), or AP-1 (AP1M) sites and treated with LPS as shown. (B) The upstream Sp1 and Egr-1 binding sites are required for LPS induction of TNF- $alpha$ . J774 cells were transfected with 2 µg of the wild-type $-$ 200 TNF- $alpha$ luciferase reporter or with isogenic reporters containing mutations in the Egr-1 and/or upstream Sp1 sites and treated with LPS as shown. Renilla luciferase (2 µg) was used to normalize transfection efficiency as shown in Fig. 2. Histograms show average results of three independent experiments; error bars represent the standard errors of the means.

We note that in contrast to induction of TNF- $alpha$ gene expression by ionophore (18, 49), induction of TNF- $alpha$ gene expressionby LPS requires an intact Sp1 site, which is also required forvirus induction of the gene (15). Furthermore, there is a secondSp1 site in the $-$ 200 TNF- $alpha$ promoter region, which is located betweennt $-$ 172 and $-$ 163 relative to the TNF- $alpha$ transcription start site.Mutation of this upstream Sp1 site also greatly reduced LPS induction,while mutation of the Egr site reduced induction of the gene byapproximately 50% (Fig. 3B), consistent with a previous study(58). Thus, the upstream Sp1 binding site, like the downstreamSp1 site, is critical for induction of the TNF- $alpha$ gene byLPS.

The composite CRE/ $kappa$ 3/ $-$ 84Ets element is sufficient for LPS induction of a truncated TNF- $alpha$ promoter. Previous studies have shown that multiple copies of the $kappa$ 3 site, which bears some resemblance to an NF- $kappa$ B binding site, donot confer LPS inducibility upon a heterologous promoter or atruncated TNF- $alpha$ promoter, consistent with the lack of bindingof NF- $kappa$ B p50 or p65 to this element in DNase I footprinting assays(49). Given the importance of the CRE and the $kappa$ 3 site in inductionof TNF- $alpha$ gene expression by LPS, we next tested whether a syntheticconstruct containing the CRE site in addition to the $kappa$ 3 site andthe $-$ 84 Ets site would be capable of conferring LPS inducibilityupon a truncated TNF- $alpha$ promoter. Only one copy of this compositeelement is sufficient to confer LPS induction upon the truncated $-$ 39 TNF- $alpha$ promoter (Fig. 4A), whereas up to six copies of the $kappa$ 3 site alone were not capable of conferring LPS inducibility(17, 58), underscoring the importance of the CRE in LPS inductionof TNF- $alpha$ gene expression. Furthermore, a mutation of the CRE,which abolishes binding of ATF-2/c-jun to the site (48), abrogatedLPS induction of this synthetic promoter construct. Intriguingly,a mutation of the 3' aspect of the $kappa$ 3 site also abrogates LPSinducibility. These results are consistent with a previous studyin THP-1 monocytic cells, which showed that two or three copiesof the composite CRE/ $kappa$ 3 element conferred LPS inducibility toa minimal simian virus 40 promoter and that this induction dependedon the integrity of the CRE and $kappa$ 3 sites (58). Moreover, thedata presented here and the study by Yao et al. demonstrate thatthe $kappa$ 3 site alone does not function as an LPS-inducible NF- $kappa$ Bsite.

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FIG. 4. Activation of the CRE/ $kappa$ 3 region of the TNF- $alpha$ promoter in response to LPS. (A) A single copy of the CRE/ $kappa$ 3 region confers LPS inducibility to a minimal TNF- $alpha$ promoter. J774 cells were transfected with 2 µg of a minimal TNF- $alpha$ promoter CAT reporter ( $-$ 39 TNF- $alpha$ CAT) CAT or reporters with one [(CRE/ $kappa$ 3)² $-$ 39 TNF- $alpha$ CAT] or two [(CRE/ $kappa$ 3)¹ $-$ 39 TNF- $alpha$ CAT] copies of the CRE/ $kappa$ 3 region. A representative CAT assay of three independent transfections is shown, illustrating CAT activity from uninduced cells and cells treated with LPS. Transfections included 2 µg of pCMV $beta$ as a control, and CAT activity was normalized to $beta$ -Gal activity. (B) The CRE and $kappa$ 3 sequences are critical for LPS inducibility of the CRE/ $kappa$ 3 region. J774 cells were transfected with luciferase reporters (2 µg) consisting of a minimal TNF- $alpha$ promoter fused to two copies of the wild-type CRE/ $kappa$ 3 sequence [(CRE/ $kappa$ 3)² $-$ 39 TNF- $alpha$ Luc] or two copies of the CRE/ $kappa$ 3 sequence with mutations in the CRE [(C1M)² $-$ 39 TNF- $alpha$ Luc] or $kappa$ 3 sequences [(3'M)² $-$ 39 TNF- $alpha$ Luc]. The mutations are shown at the bottom of the figure. Histograms of luciferase activity from five independent experiments are shown; error bars indicate the standard errors of the means. All transfections included a control Renilla luciferase plasmid (2 µg), and reporter luciferase activity was normalized to Renilla luciferase activity. UN, uninduced.

ERK and ATF-2 are required for LPS induction of TNF- $alpha$ . Stimulation of the monocyte lineage by LPS triggers the activation of the MAPKs ERK, JNK, and p38 (reviewed in reference 12).Phosphorylation of Ets proteins is generally dependent upon MAPKs(reviewed in reference 53). For example, upon LPS stimulationof macrophages, the Ets protein Elk-1 is phosphorylated via theERK pathway (39). LPS activation of the Ets protein PU.1 isdependent upon a distinct pathway involving protein kinase CK2(30), which is in turn ERK dependent (35). The transcriptionalactivity of c-jun is dependent upon phosphorylation by JNK, whilethat of ATF-2 is dependent upon JNK or p38 (reviewed in reference56). By contrast, NFAT proteins are targeted by the calcium-dependentphosphatase calcineurin, which is selectively inhibited by CsA(reviewed in references 11 and 38).

In order to investigate the role of these distinct signal transduction pathways in LPS induction of TNF- $alpha$ gene expression,we performed quantitative RNase protection assays in J774 cellsusing inhibitors of p38 (SB203580), ERK (PD98059), and calcineurin(CsA). As shown in Fig. 5A, LPS induction of TNF- $alpha$ mRNA levelswas selectively inhibited (approximately 50%) by the ERK inhibitorPD98059 at a concentration of 10 µM (compare lanes 2 and 4) andwas not affected by CsA (lane 7) or the p38 inhibitor SB203580even up to a concentration of 20 µM (lanes 10 to 13). Thus, ERKbut not p38 or calcineurin activity is required for full inductionof TNF- $alpha$ transcription by LPS in J774 cells.

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FIG. 5. LPS-stimulated TNF- $alpha$ induction is dependent upon ERK and ATF-2 but not calcineurin, p38, or NFATp. (A) ERK-dependent TNF- $alpha$ mRNA induction by LPS. Autoradiograms of RNase protection assays mapping TNF- $alpha$ and $gamma$ -actin mRNAs from untreated (UN) or LPS-stimulated J774 cells in the absence or presence of the ERK inhibitor PD98059, the calcineurin inhibitor CsA, or the p38 inhibitor SB203580 are shown. RNA was analyzed 1 h poststimulation, and inhibitors were added 10 min prior to LPS stimulation. Concentrations were as follows: PD98059, 2, 10, 20, and 30 µM (lanes 3 to 6); CsA, 1 µM (lane 7); and SB203580, 1, 5, 10, and 20 µM (lanes 10 to 13). We note that TNF- $alpha$ -stimulated TNF- $alpha$ gene transcription is inhibited by SB203580 at a concentration of 10 µM (6). (B) Activation of ERK by LPS. A Western blot of total ERK1/2 and phosphorylated ERK1/2 from untreated or LPS-stimulated J774 cells in the presence or absence of PD98059 is shown. Nuclear extracts were prepared from J774 cells stimulated with LPS for 15 min in the presence or absence of pretreatment (10 min) with 10 µM PD98059. Extracts were analyzed by sodium dodecyl sulfate-6% polyacrylamide gel electrophoresis, and Western analysis was performed using antibodies to phosphorylated ERK1/2 (bottom), followed by reprobing with an antibody against ERK1/2 (top) to ensure equal protein loading in all samples. The result displayed is representative of three independent experiments. (C) Induction of TNF- $alpha$ by LPS is impaired in ATF-2 mutant mice. Results of an RNase protection assay of spleen cells from wild-type (ATF-2^+/+) and ATF-2 mutant (ATF-2^m/m) mice using TNF- $alpha$ and $gamma$ -actin probes as described for panel A are shown. Mice were injected with LPS intraperitoneally, and spleens were collected 2 h later. (D) Induction of TNF- $alpha$ by LPS is not impaired in NFATp-deficient mice. Results of an RNase protection assay of spleen cells from wild-type (NFATp^+/+) and NFATp-deficient (NFATp^/) mice using TNF- $alpha$ and $gamma$ -actin probes as described for panel A are shown. Spleens were isolated from the mice and stimulated in vitro with LPS for 1 h.

To confirm that ERK was activated by LPS, we next performed a Western blot analysis using nuclear extracts from J774 cellsand a specific antibody to the phosphorylated forms of ERK1 andERK2. As shown in Fig. 5B, the phosphorylated ERK levels werestimulated by LPS, while total ERK levels were unaffected (comparelanes 1 and 3). The LPS-induced levels of phosphorylated ERK werein turn inhibited by PD98059 (lane 4). Thus, in J774 cells, LPSstimulation leads to activation of ERK1/2 through phosphorylationof specific tyrosine residues, and PD98059 functions as an inhibitorof LPS-induced ERKphosphorylation.

Parallel RNase protection assays to assess the role of JNK in LPS-mediated TNF- $alpha$ transcription were not possible due to thelack of JNK-specific inhibitory compounds, so instead we focusedon the role of a downstream target of JNK and p38, ATF-2, whichbinds the TNF- $alpha$ CRE site (48). Using RNase protection assays,we examined LPS-stimulated TNF- $alpha$ gene regulation in mice homozygousfor a mutant form of the ATF-2 gene (40). As shown in Fig. 5C,constitutive and LPS-stimulated TNF- $alpha$ mRNA levels were reducedapproximately 50% in spleens from ATF-2 mutant mice compared tolevels in wild-type littermates (compare lanes 1 and 3 to lanes2 and 4). For comparison, we also examined LPS-stimulated TNF- $alpha$ mRNA levels in mice deficient in NFATp (23). Consistent withour finding that LPS induction of TNF- $alpha$ was not sensitive to CsA,LPS-stimulated TNF- $alpha$ mRNA levels from NFATp-deficient and wild-typemice were equivalent (Fig. 5D, compare lanes 1 and 3 to 2 and4). Taken together, these results establish that ERK and ATF-2,but not p38, calcineurin, or NFATp, play a critical role in inductionof TNF- $alpha$ transcription by LPS. These findings are consistent withresults of multiple studies that support a role for ERK in LPS-mediatedTNF- $alpha$ transcription and protein synthesis in macrophages (3,16, 31, 41, 51, 52).

Ets proteins bind to three sites in the TNF- $alpha$ promoter. Although our results indicated that induction of the TNF- $alpha$ gene by LPS did not involve calcineurin or NFATp, induction ofthe TNF- $alpha$ gene by LPS was strongly inhibited by mutation of the $-$ 117-NFAT, $-$ 76-NFAT, and $kappa$ 3-NFAT sites (Fig. 3A). Since the bindingsites for NFAT and Ets proteins both contain a 5'-GGAA-3' coreelement, we next examined the binding of the ERK-dependent Etsproteins Elk-1, Ets-1, and PU.1 to the TNF- $alpha$ promoter by quantitativeDNase I footprinting, using NFATp for comparison. We note thatproteins that recognize Ets-like binding motifs, such as Ets-1(26) and C/EBP $beta$ (37), have previously been implicated in TNF- $alpha$ gene regulation in T cells and myelomonocytic cells,respectively.

As shown in Fig. 6, two regions of the TNF- $alpha$ promoter are protected by Ets-1 (Fig. 6A) and Elk-1 (Fig. 6B). Notably, theseregions overlap the $-$ 117-NFAT and $-$ 76-NFAT sites (49). Moreover,the latter protected region overlaps an Elk-1 consensus site (43)located between nt $-$ 84 and $-$ 80. We also note that the region containingthe $-$ 117-NFAT site was previously shown to bind Ets in a gel shiftassay (26). By contrast, however, binding of PU.1 at the sameconcentrations used for Ets-1 and Elk-1 was not discernible (Fig.6B). Since the $-$ 76, $-$ 84, and $kappa$ 3-3' mutations compromise inductionof TNF- $alpha$ by LPS (Fig. 3A), we next examined the effects of thesemutations upon Ets protein binding.

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FIG. 6. Ets-1 and Elk-1 bind to three sites in the TNF- $alpha$ promoter. (A) Ets-1 binds to the $-$ 84 Ets and the $-$ 76- and $-$ 117-NFAT sites. Quantitative DNase I footprinting using the wild-type human TNF- $alpha$ promoter (nt $-$ 200 to +87 relative to the transcription start site) and increasing concentrations of recombinant NFATp or Ets-1 (20 ng, 100 ng, 400 ng, and 2 µg) is shown. The positions of the $kappa$ 3, $-$ 76, $-$ 84, and $-$ 117 binding sites are shown. NFATp binds with high affinity to $kappa$ 3 and $-$ 76 and with lower affinity to $-$ 117 and a novel site centered around $-$ 55 (Tsytsykova and Goldfeld, unpublished data). (B) Elk-1 binds to the $-$ 84 Ets and the $-$ 76- and $-$ 117-NFAT sites. Quantitative DNase I footprinting using the wild-type human TNF- $alpha$ promoter (nt $-$ 200 to +87 relative to the transcription start site) and increasing concentrations of recombinant NFATp or Elk-1 (20 ng, 100 ng, 400 ng, and 2 µg) is shown. Two independent preparations of PU.1 (gifts of H. Singh and B. Nikolajczyk) were tested, and no binding of PU.1 with significant affinity was observed.

The region protected by Elk-1 near the $-$ 76-NFAT site overlaps two 5'-GGAA-3' Ets-binding motifs at positions $-$ 76 and $-$ 84 (Fig.7). Mutation of the $-$ 76-NFAT site, however, did not abolish bindingof Elk-1 to the $-$ 84 site (Fig. 7B); conversely, mutation of the $-$ 84 site did not abolish binding of Elk-1 to the $-$ 76-NFAT site(Fig. 7C). We note that using the $-$ 84 mutant template, at thehighest concentrations of Elk-1, some additional binding to adownstream GGA sequence overlapping a novel NFAT site at $-$ 55 (A.V. Tsytsykova and A. E. Goldfeld, unpublished data) not normallyprotected is observed (Fig. 7C). Thus, two distinct Ets sitesare discernible by DNase I footprinting using mutant TNF- $alpha$ promotertemplates. In results consistent with those of previous studies,mutation of the Ets-Elk motif that overlaps the $-$ 117 NFAT siteabrogated binding of Elk-1 to the site (Fig. 7E and F). We notethat for the $-$ 113 M template, in which only one base pair of theEts-Elk site is altered, some binding of Elk-1 was discernible,but only at the highest protein concentrations (Fig. 7E).

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FIG. 7. Mutation of the $-$ 76-NFAT, $kappa$ 3-NFAT, $-$ 117-NFAT, or $-$ 84 sites in the TNF- $alpha$ promoter inhibit Elk-1 binding. Quantitative DNase I footprinting using the wild-type human TNF- $alpha$ promoter (nt $-$ 200 to +87 relative to the transcription start site) (A) or isogenic probes bearing mutations in the $-$ 76-NFAT site ( $-$ 76M) (B), the $-$ 84 Elk-Ets site ( $-$ 84M) (C), or the $kappa$ 3 site (3'M) (D), as well as two mutations in the $-$ 117-NFAT site, $-$ 117M (E) and $-$ 113M (F), is shown. The sequences of the mutant sites are shown at the bottom of the figure. Probes were incubated with increasing concentrations of recombinant Elk-1 (50 ng, 200 ng, or 1 µg). Alterations in the cleavage pattern observed with the $-$ 76-NFAT and $kappa$ 3-NFAT mutant templates in the vicinity of the $-$ 84 Ets-Elk site are indicated with arrows (B to D).

Mutation of the 3' aspect of the $kappa$ 3-NFAT site ( $kappa$ 3 3'M), like mutation of the $-$ 76-NFAT and $-$ 84 sites, changed the cleavagepattern by DNase I on the naked DNA template. We note that thecleavage pattern of the naked $-$ 76 mutant template significantlyvaried from that of the wild-type template in this region (compareFig. 7A and D). At the highest concentrations of Elk-1, partialprotection of this altered cleavage pattern on the mutant templatewas observed; however, even at the highest concentrations of Elk-1there was not full protection of this site, consistent with itsdeleterious effect upon LPS-stimulated TNF- $alpha$ gene induction. Strikingly,the $kappa$ 3 3'M mutation not only caused a change in the cleavage patternin the vicinity of the nearby $-$ 84 site but also inhibited bindingof Elk-1 to the site (Fig. 7D). Thus, the inhibition of LPS-stimulatedTNF- $alpha$ gene expression by the $-$ 76, $-$ 84, and $kappa$ 3 3' mutations isconsistent with their interference with Ets and Elk binding tothe $-$ 76 and $-$ 84-Ets-Elksites.

Elk-1, Ets, ATF-2-Jun, Egr1, and Sp1 proteins interact with the endogenous TNF- $alpha$ promoter upon LPS stimulation. To establish which of the transcriptional activator proteins bind to the TNF- $alpha$ promoter in J774 cells in vivo, we next performedChIP assays using specific antibodies against the different activators.This technique has been used to detect binding of transcriptionfactors to the beta interferon promoter following virus infection(55) and to the TNF- $alpha$ promoter following virus infection andionophore stimulation (15). TNF- $alpha$ promoter DNA was amplifiedby PCR of formaldehyde-fixed chromatin immunoprecipitated by theantibodies shown in Fig. 8, which provided an indication of theamount of transcription factor binding to the promoter followingstimulation by LPS in vivo. Based on our site-directed mutagenesisstudies of the TNF- $alpha$ promoter function, characterization of theupstream signaling pathways involved in LPS induction of the gene,and quantitative DNase I footprinting, we used antibodies directedagainst proteins that recognize Ets binding sites (Ets-1 and -2,Elk-1, C/EBP $beta$ ), the CRE (ATF-2 and c-jun), and the Sp1 and Egr-1sites. As shown in Fig. 8, LPS stimulation of J774 cells resultedin the inducible binding of Ets-1 and -2, Elk-1, ATF-2, c-jun,Egr-1, and Sp1 to the TNF- $alpha$ promoter in vivo. By contrast, bindingof C/EBP $beta$ to the TNF- $alpha$ promoter was not induced by LPS, consistentwith the observation that macrophages from mice lacking C/EBP $beta$ produce wild-type levels of TNF- $alpha$ mRNA following LPS stimulation(45).

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FIG. 8. LPS-induced binding of transcription factors to the endogenous TNF- $alpha$ promoter. Formaldehyde cross-linking and chromatin immunoprecipitation of unstimulated and LPS-stimulated J774 cells are shown. Following induction, cells were treated with formaldehyde to cross-link endogenous protein and DNA. Samples of sonicated and purified chromatin were immunoprecipitated with the indicated antibodies, and DNA isolated from immunoprecipitated material was amplified by PCR with primers specific for the TNF- $alpha$ gene. An increase in the relative amount of the amplified TNF- $alpha$ promoter-specific PCR product indicates binding of the protein to the endogenous TNF- $alpha$ promoter. Control amplifications with buffer, genomic DNA (gDNA), or the chromatin used as input for the immunoprecipitations are shown, along with a 123-bp marker (Life Technologies). We used the human immunodeficiency virus type 1 long terminal repeat as a template in the ChIP analysis as a positive control for the C/EBP $beta$ antibody (B. M. N. Brinkman and A. E. Goldfeld, unpublished data).

Due to the variable sizes of promoter DNA fragments that are generated when DNA is sheared in the ChIP assay (36), bindingof factors to nonfunctional flanking sequences can also be detectedin this sensitive assay. Thus, correlation of findings obtainedwith ChIP with functional data, including the roles of specificpromoter binding sites, is necessary. We note that LPS causessome calcium influx in J774 cells (54), which would be expectedto activate calcineurin and cause the nuclear translocation ofNFAT proteins, and that LPS also causes the phosphorylation ofI $kappa$ B, resulting in the nuclear translocation of NF- $kappa$ B (reviewedin reference 46). Consistent with these observations, we detectedbinding of NFAT and p50-p65 proteins to the TNF- $alpha$ promoter uponLPS treatment of J774 cells (data not shown). However, inductionof TNF- $alpha$ gene transcription by LPS is insensitive to CsA and isnot compromised in NFATp-deficient mice. Furthermore, the onlyNF- $kappa$ B-like site in the $-$ 200 TNF- $alpha$ promoter that is required formaximal induction by LPS, $kappa$ 3, does not bind high concentrationsof recombinant p50-p65 in DNase I footprinting assays (49),nor does it confer LPS inducibility upon a heterologous promoteras would a functional NF- $kappa$ B site (17, 58). We thus concludethat NFAT binds to the subset of TNF- $alpha$ NFAT sites and/or NFATsites in flanking sequences of no functional relevance in LPSstimulation, and that p50-p65 proteins bind to nonfunctional NF- $kappa$ Bmotifs, which are in flanking sequences not involved in LPS-stimulatedTNF- $alpha$ geneexpression.

Taken together, the LPS-inducible recruitment of ATF-2, c-jun, Ets, Elk-1, and Sp1 to the TNF- $alpha$ promoter observed in the ChIPanalysis strongly correlates with the critical functional rolesthat the Sp1, CRE, Ets, and Egr-1 TNF- $alpha$ promoter sites play inthe activation of the gene byLPS.

CBP and p300 proteins are required for LPS stimulation of TNF- $alpha$ and are transcriptionally activated by LPS. CBP and p300 proteins play a critical role in the induction of TNF- $alpha$ transcription by virus and T cell receptor ligands (14).CBP and p300 proteins function as coactivators for multiple transcriptionfactors (reviewed in reference 42). We thus next examined thepotential role of these proteins in TNF- $alpha$ gene expression in responseto LPS. Using the adenovirus E1A 12S protein, which inhibits CBPand p300 function (13), we performed cotransfection studieswith the TNF- $alpha$ luciferase reporter gene in J774 cells. As a control,we used a mutant form of the E1A 12S protein (E1A 12S $Delta$ 2-36),which lacks the CBP and p300 interaction domain and fails to inhibitCBP and p300 activity (28). As shown in Fig. 9A, activationof the TNF- $alpha$ reporter upon stimulation of J774 cells with LPSwas inhibited by E1A 12S but not by E1A 12S $Delta$ 2-36, indicatinga specific role for CBP and p300 coactivators in LPS-mediatedTNF- $alpha$ transcription.

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FIG. 9. CBP and p300 proteins mediate LPS induction of TNF- $alpha$ . (A) Inhibition of CBP and p300 impairs TNF- $alpha$ transcription induced by LPS. J774 cells were cotransfected with 2 µg of $-$ 200 TNF- $alpha$ luciferase reporter and 2 µg of the vectors expressing wild-type or mutant ( $Delta$ 2-36) forms of E1A 12S. Wild-type E1A represses CBP and p300 activity, while the mutant form does not. Histograms of uninduced (UN) or LPS-induced cells are shown, representing at least three independent experiments. Cotransfection of an empty vector with luciferase reporter yielded results essentially identical to those obtained with E1A( $Delta$ 2-36) (data not shown). Transfection efficiency was normalized as described in the legend to Fig. 2, and error bars represent the standard errors of the means. (B) The CRE/ $kappa$ 3/Ets sequence functions as a CBP- and p300-dependent element. J774 cells were cotransfected with (CRE/ $kappa$ 3)² $-$ 39 TNF- $alpha$ luciferase reporter and vectors expressing wild-type or mutant E1A 12S and analyzed as described above. Histograms of uninduced and LPS-induced cells are shown, representing at least three independent experiments; error bars represent the standard errors of the means. Cotransfection of empty vector with luciferase reporter yielded results essentially identical to those obtained with E1A( $Delta$ 2-36) (data not shown). (C) LPS potentiates transcriptional activity of CBP and p300. J774 cells were cotransfected with a Gal4-dependent luciferase reporter (2 µg) and vectors expressing full-length CBP or p300 fused to the Gal4 DNA-binding domain (0.2, 0.7, or 2 µg) or the Gal4 DNA-binding domain alone (2 µg). The fold induction of LPS-induced activity relative to uninduced activity is shown. The total amount of DNA was kept constant with empty vector. Assays were quantified as described above. (D) Model of an LPS-specific TNF- $alpha$ enhancer complex. A diagram of TNF- $alpha$ promoter elements and the cognate transcription factors recruited upon LPS stimulation is shown. These factors are known to interact, constitutively or inducibly, with CBP and p300 proteins, which are required for LPS induction of TNF- $alpha$ gene expression.

We next tested the effect of inhibition of CBP and p300 upon the synthetic promoter construct containing two copies of the $-$ 117 to $-$ 80 sequence fused to a truncated $-$ 39 TNF- $alpha$ promoter.We have shown that this sequence, which includes the compositeCRE/ $kappa$ 3 element and the flanking Ets-Elk sites at nt $-$ 117 and $-$ 84,is highly inducible by LPS (Fig. 4A). Induction of the (CRE/ $kappa$ 3/Ets)² reporter construct was also blocked by E1A 12S but not by E1A12S $Delta$ 2-36 (Fig. 9B). Thus, the CRE/ $kappa$ 3/Ets element is sufficientfor functional interaction with the coactivator proteins CBP andp300 in LPS-mediated TNF- $alpha$ geneexpression.

CBP and p300 contain transcriptional activation domains (9, 32). Thus, our results raised the possibility that the transactivationof CBP and p300 proteins might be potentiated by LPS. To examinethis, we used CBP or p300 proteins fused to the DNA binding domainof Gal4 to determine the effect of LPS stimulation upon Gal4 bindingsite-dependent transcription. Strikingly, both Gal4-CBP and Gal4-p300were activated in response to LPS stimulation (Fig. 9C). We notethat the levels of transcriptional activity of CBP induced byLPS stimulation were consistently higher than those of p300 (Fig.9C). Taken together, these data provide the first demonstrationof a role for the CBP and p300 proteins in LPS-mediated gene expressionand furthermore demonstrate that LPS-stimulated assembly of theTNF- $alpha$ enhancer complex is CBP and p300 coactivatordependent.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

We have shown that LPS-induced activation of TNF- $alpha$ gene transcription in macrophages leads to the formation of a distinctenhancer complex that includes transcription factors that bindthe CRE, Egr, Ets, and Sp1 sites in the promoter. Strikingly,a set of core promoter elements, which comprise functional NFATbinding sites required for induction of the gene by calcineurin-dependentstimuli, are also functional binding sites for the ERK-targetedEts and Elk proteins in LPS-stimulated TNF- $alpha$ geneexpression.

We previously demonstrated that the TNF- $alpha$ gene is regulated in a cell-type-specific manner in T and B cells activated throughtheir antigen receptors through the differential binding of NFATto the same composite promoter element, the CRE/ $kappa$ 3 site (49).In more recent studies, we have shown that within a specific celltype, two different stimuli result in the formation of a distinctset of protein complexes at the TNF- $alpha$ promoter. Specifically,in T and B cells, ionophore stimulation leads to the formationof a nucleoprotein complex containing ATF-2-c-jun and NFATp, whilevirus infection leads to the formation of a nucleoprotein complexcontaining ATF-2-c-jun and NFATp and Sp1 (15).

Here, we have characterized the TNF- $alpha$ enhancer complex that forms upon LPS stimulation of macrophages and find that thereis no role for NFAT proteins. Rather, the Ets proteins Ets-1 andElk-1, in combination with ATF-2-c-jun, Sp1, and Egr-1, are involvedin LPS-mediated TNF- $alpha$ gene transcription. Furthermore, a givenset of promoter elements that match Ets-Elk and NFAT motifs inthe TNF- $alpha$ promoter are functional sites for distinct proteins,depending on the stimulus. In the case of T cell receptor engagementand ionophore stimulation, these sites are functional NFAT motifs(15, 18, 49). By contrast, in the case of LPS stimulation,these sites are no longer functional NFAT motifs but rather canfunction as binding sites for the Ets proteins Elk-1 and Ets-1in vitro and in vivo. Thus, this study demonstrates that a genecan respond to different signaling pathways through the recruitmentof different proteins to the same enhancerelement.

Similar to virus infection, LPS-induced TNF- $alpha$ gene transcription also involves the inducible binding of Sp1, generally consideredto be a constitutive transcription factor. Notably, quantitativeDNase I footprinting reveals that both of the TNF- $alpha$ promoter Sp1sites are in fact low-affinity Sp1 sites (Tsytsykova and Goldfeld,unpublished observations). Thus, inducible rather than constitutiveSp1 binding correlates with the relatively lower affinity of Sp1for its binding sites in the TNF- $alpha$ promoter and with its inducer-specificrequirement in TNF- $alpha$ gene regulation. There is no evidence ofcooperative binding between Sp1 and the other activators involvedin TNF- $alpha$ gene regulation by LPS, since binding of Sp1 with Elk-1,ATF-2/c-jun, or NFATp is not cooperative in quantitative DNaseI footprinting analyses (Tsytsykova and Goldfeld, unpublisheddata). Inducer-specific recruitment of Sp1 might thus be achievedby enhancing the affinity of Sp1 for these binding sites in theTNF- $alpha$ promoter via posttranslational modification or by inducinga change in the accessibility of the sites in the context ofchromatin.

Our findings also demonstrate a role for the CRE site in LPS-induced TNF- $alpha$ gene transcription and have shown the induciblerecruitment of ATF-2 and c-jun to the TNF- $alpha$ promoter by LPS invivo. Our results with ATF-2 mutant mice further demonstrate arole for ATF-2 in LPS activation of TNF- $alpha$ gene transcription.The CRE site and binding of ATF-2-Jun to this site are requiredfor induction of the TNF- $alpha$ gene by calcium ionophore or antigenreceptor engagement of T and B cells (48, 49), by Fc $varepsilon$ RI engagementin mast cells (21), by TNF- $alpha$ treatment in fibroblasts (6),and by virus infection of T and B cells and fibroblasts (15).Thus, binding of ATF-2-Jun to the TNF- $alpha$ CRE is the endpoint ofdistinct signal transduction pathways that are set into motionby multiple extracellular stimuli that induce TNF- $alpha$ gene expression,and this site serves to integrate these various signals at thelevel oftranscription.

The CBP and p300 transactivation domains were initially characterized as targets of protein kinase A (9, 32), and ithas recently been shown that transactivation mediated by CBP ispotentiated by calcium influx and by nerve growth factor in neuronalcells (8, 29). Here, we have demonstrated that the transcriptionalactivity of CBP and p300 is also potentiated by LPS. Moreover,in our studies of TNF- $alpha$ , we have established a role for the CBPand p300 proteins in LPS-mediated expression of a specific gene.The CBP and p300 proteins function as transcriptional integrators,interacting with multiple transcription factors and the basaltranscription machinery (reviewed in reference 42). Our demonstrationthat the CRE/ $kappa$ 3 element is sufficient for functional interactionwith the coactivator proteins CBP and p300 is therefore consistentwith the role of this composite element in integrating diversesignal transduction pathways at the TNF- $alpha$ promoter.

Notably, all of the transcription factors we have detected binding to the TNF- $alpha$ promoter in vivo upon LPS stimulation (ATF-2,c-jun, Ets, Elk-1, Egr-1, and Sp1) have been shown to interactwith CBP and p300 in an inducible or constitutive manner (2,4, 24, 25, 44, 57). We thus model the LPS-induced enhancercomplex at the TNF- $alpha$ promoter as a complex involving multipleinteractions between the DNA-bound transcription factors and theCBP and p300 coactivators (Fig. 9D).

Assembly of transcription factors into higher-order nucleoprotein complexes, or enhanceosomes, typically ensures that a geneis transcribed in response to a given stimulus (reviewed in references7 and 34). In the case of the TNF- $alpha$ promoter, distinct setsof transcription factors are recruited to a fixed set of bindingsites depending upon the stimulus. This finding thus illustratesa mechanism by which a single gene may respond to distinct inductionsignals through the same regulatory region and may indeed be ageneral means by which temporal and stimulus-specific transcriptionisachieved.

	ACKNOWLEDGMENTS

We thank Tom Maniatis for comments on the manuscript and for research support to J.V.F. Critical support was also providedby Fred Rosen and The Center for Blood Research. We gratefullyacknowledge the generosity of the following individuals who providedessential reagents for this study: Dimitris Thanos (NFATp proteinand Gal4-CBP), Harinder Singh (PU.1 protein), Andrew Sharrocks(Elk-1 protein), and Barbara Nikolajczyk (Ets-1 and PU.1 proteins).We also thank the following individuals for their generous gifts:L.-L. Lin and Genetics Institute for SB203580, G. Cox for theANA-1 cells, H. W. L. Ziegler-Heitbrock for the Mono Mac-6 cells,A. Giordano and Y. Shi for Gal 4-p300, T. Collins for the E1Aexpression vectors, T. Kawakami for the $-$ 200 TNF- $alpha$ luciferasereporter, and Jessica Leung and Patricia Pesavento for assistancewithtransfections.

This work was supported by grants from the NIH to A.E.G. (GM-56492) and L.H.G. (AI-32412), a gift from the G. Harold and LeilaY. Mathers Charitable Foundation to L.H.G., a grant from the ArthritisFoundation to A.M.R., and an Established Investigator Award fromthe American Heart Association to A.E.G.

E.Y.T., J.V.F., and A.V.T. made equal contributions to thiswork.

	FOOTNOTES

^* Corresponding author. Mailing address: The Center for Blood Research and Harvard Medical School, 800 Huntington Ave., Boston,MA 02115. Phone: (617) 278-3351. Fax: (617) 278-3454. E-mail:goldfeld{at}cbr.med.harvard.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Aggarwal, B. B., and R. K. Puri. 1995. Human cytokines: their role in disease and therapy. Blackwell Science, Cambridge, Mass.

2. Arias, J., A. S. Alberts, P. Brindle, F. X. Claret, T. Smeal, M. Karin, J. Feramisco, and M. Montminy. 1994. Activation of cAMP and mitogen responsive genes relies on a common nuclear factor. Nature 370:226-229[CrossRef][Medline].

3. Baldassare, J. J., Y. Bi, and C. J. Bellone. 1999. The role of p38 mitogen-activated protein kinase in IL-1 $beta$ transcription. J. Immunol. 162:5367-5373[Abstract/Free Full Text].

4. Billon, N., D. Carlisi, M. B. Datto, L. A. van Grunsven, A. Watt, X.-F. Wang, and B. B. Rudkin. 1999. Cooperation of Sp1 and p300 in the induction of the CDK inhibitor p21WAF1/CIP1 during NGF-mediated neuronal differentiation. Oncogene 18:2872-2882[CrossRef][Medline].

5. Boehm, J. C., J. M. Smietana, M. E. Sorenson, R. S. Garigipati, T. F. Gallagher, P. L. Sheldrake, J. Bradbeer, A. M. Badger, J. T. Laydon, J. C. Lee, L. M. Hillegass, D. E. Griswold, J. J. Breton, M. C. Chabot-Fletcher, and J. L. Adams. 1996. 1-substituted 4-aryl-5-pyridinylimidazoles: a new class of cytokine suppressive drugs with low 5-lipoxygenase and cyclooxygenase inhibitory potency. J. Med. Chem. 39:3929-3937[CrossRef][Medline].

6. Brinkman, B. M. N., J.-B. Telliez, A. R. Schievella, L.-L. Lin, and A. E. Goldfeld. 1999. Engagement of TNF receptor 1 leads to ATF-2 and p38 MAP kinase-dependent TNF- $alpha$ gene expression. J. Biol. Chem. 274:30882-30886[Abstract/Free Full Text].

7. Carey, M. 1998. The enhanceosome and transcriptional synergy. Cell 92:5-8[CrossRef][Medline].

8. Chawla, S., G. E. Hardingham, D. R. Quinn, and H. Bading. 1998. CBP: a signal-regulated transcriptional coactivator controlled by nuclear calcium and CaM kinase IV. Science 281:1505-1509[Abstract/Free Full Text].

9. Chrivia, J. C., R. P. Kwok, N. Lamb, M. Hagiwara, M. R. Montminy, and R. H. Goodman. 1993. Phosphorylated CREB binds specifically to the nuclear protein CBP. Nature 365:855-859[CrossRef][Medline].

10. Cox, G. W., B. J. Mathieson, L. Gandino, E. Blasi, D. Radzioch, and L. Varesio. 1989. Heterogeneity of hematopoietic cells immortalized by v-myc/v-raf recombinant retrovirus infection of bone marrow or fetal liver. J. Natl. Cancer Inst. 81:1492-1496[Abstract/Free Full Text].

11. Crabtree, G. R. 1999. Generic signals and specific outcomes: signaling through Ca2+, calcineurin, and NF-AT. Cell 96:611-614[CrossRef][Medline].

12. DeFranco, A. L., M. T. Crowley, A. Finn, J. Hambleton, and S. L. Weinstein. 1998. The role of tyrosine kinases and map kinases in LPS-induced signaling. Prog. Clin. Biol. Res. 397:119-136[Medline].

13. Eckner, R., M. E. Ewen, D. Newsome, M. Gerdes, J. A. DeCaprio, J. B. Lawrence, and D. M. Livingston. 1994. Molecular cloning and functional analysis of the adenovirus E1A-associated 300-kD protein (p300) reveals a protein with properties of a transcriptional adaptor. Genes Dev. 8:869-884[Abstract/Free Full Text].

14. Falvo, J. V., B. M. N. Brinkman, A. V. Tsytsykova, E. Y. Tsai, T.-P. Yao, A. L. Kung, and A. E. Goldfeld. 2000. A stimulus-specific role for CREB-binding protein (CBP) in T cell receptor-activated tumor necrosis factor $alpha$ gene expression. Proc. Natl. Acad. Sci. USA 97:3925-3929[Abstract/Free Full Text].

15. Falvo, J. V., A. M. Uglialoro, B. N. M. Brinkman, M. Merika, B. S. Parekh, H. C. King, E. Y. Tsai, A. D. Morielli, E. G. Peralta, T. Maniatis, D. Thanos, and A. E. Goldfeld. 2000. Stimulus-specific assembly of enhancer complexes on the tumor necrosis factor alpha gene promoter. Mol. Cell. Biol. 20:2239-2247[Abstract/Free Full Text].

16. Geppert, T. D., C. E. Whitehurst, P. Thompson, and B. Beutler. 1994. Lipopolysaccharide signals activation of tumor necrosis factor biosynthesis

1.	Aggarwal, B. B., and R. K. Puri. 1995. Human cytokines: their role in disease and therapy. Blackwell Science, Cambridge, Mass.
2.	Arias, J., A. S. Alberts, P. Brindle, F. X. Claret, T. Smeal, M. Karin, J. Feramisco, and M. Montminy. 1994. Activation of cAMP and mitogen responsive genes relies on a common nuclear factor. Nature 370:226-229[CrossRef][Medline].
3.	Baldassare, J. J., Y. Bi, and C. J. Bellone. 1999. The role of p38 mitogen-activated protein kinase in IL-1 $beta$ transcription. J. Immunol. 162:5367-5373[Abstract/Free Full Text].
4.	Billon, N., D. Carlisi, M. B. Datto, L. A. van Grunsven, A. Watt, X.-F. Wang, and B. B. Rudkin. 1999. Cooperation of Sp1 and p300 in the induction of the CDK inhibitor p21WAF1/CIP1 during NGF-mediated neuronal differentiation. Oncogene 18:2872-2882[CrossRef][Medline].
5.	Boehm, J. C., J. M. Smietana, M. E. Sorenson, R. S. Garigipati, T. F. Gallagher, P. L. Sheldrake, J. Bradbeer, A. M. Badger, J. T. Laydon, J. C. Lee, L. M. Hillegass, D. E. Griswold, J. J. Breton, M. C. Chabot-Fletcher, and J. L. Adams. 1996. 1-substituted 4-aryl-5-pyridinylimidazoles: a new class of cytokine suppressive drugs with low 5-lipoxygenase and cyclooxygenase inhibitory potency. J. Med. Chem. 39:3929-3937[CrossRef][Medline].
6.	Brinkman, B. M. N., J.-B. Telliez, A. R. Schievella, L.-L. Lin, and A. E. Goldfeld. 1999. Engagement of TNF receptor 1 leads to ATF-2 and p38 MAP kinase-dependent TNF- $alpha$ gene expression. J. Biol. Chem. 274:30882-30886[Abstract/Free Full Text].
7.	Carey, M. 1998. The enhanceosome and transcriptional synergy. Cell 92:5-8[CrossRef][Medline].
8.	Chawla, S., G. E. Hardingham, D. R. Quinn, and H. Bading. 1998. CBP: a signal-regulated transcriptional coactivator controlled by nuclear calcium and CaM kinase IV. Science 281:1505-1509[Abstract/Free Full Text].
9.	Chrivia, J. C., R. P. Kwok, N. Lamb, M. Hagiwara, M. R. Montminy, and R. H. Goodman. 1993. Phosphorylated CREB binds specifically to the nuclear protein CBP. Nature 365:855-859[CrossRef][Medline].
10.	Cox, G. W., B. J. Mathieson, L. Gandino, E. Blasi, D. Radzioch, and L. Varesio. 1989. Heterogeneity of hematopoietic cells immortalized by v-myc/v-raf recombinant retrovirus infection of bone marrow or fetal liver. J. Natl. Cancer Inst. 81:1492-1496[Abstract/Free Full Text].
11.	Crabtree, G. R. 1999. Generic signals and specific outcomes: signaling through Ca2+, calcineurin, and NF-AT. Cell 96:611-614[CrossRef][Medline].
12.	DeFranco, A. L., M. T. Crowley, A. Finn, J. Hambleton, and S. L. Weinstein. 1998. The role of tyrosine kinases and map kinases in LPS-induced signaling. Prog. Clin. Biol. Res. 397:119-136[Medline].
13.	Eckner, R., M. E. Ewen, D. Newsome, M. Gerdes, J. A. DeCaprio, J. B. Lawrence, and D. M. Livingston. 1994. Molecular cloning and functional analysis of the adenovirus E1A-associated 300-kD protein (p300) reveals a protein with properties of a transcriptional adaptor. Genes Dev. 8:869-884[Abstract/Free Full Text].
14.	Falvo, J. V., B. M. N. Brinkman, A. V. Tsytsykova, E. Y. Tsai, T.-P. Yao, A. L. Kung, and A. E. Goldfeld. 2000. A stimulus-specific role for CREB-binding protein (CBP) in T cell receptor-activated tumor necrosis factor $alpha$ gene expression. Proc. Natl. Acad. Sci. USA 97:3925-3929[Abstract/Free Full Text].
15.	Falvo, J. V., A. M. Uglialoro, B. N. M. Brinkman, M. Merika, B. S. Parekh, H. C. King, E. Y. Tsai, A. D. Morielli, E. G. Peralta, T. Maniatis, D. Thanos, and A. E. Goldfeld. 2000. Stimulus-specific assembly of enhancer complexes on the tumor necrosis factor alpha gene promoter. Mol. Cell. Biol. 20:2239-2247[Abstract/Free Full Text].
16.	Geppert, T. D., C. E. Whitehurst, P. Thompson, and B. Beutler. 1994. Lipopolysaccharide signals activation of tumor necrosis factor biosynthesis