Advertisement

Two NFAT Transcription Factor Binding Sites Participate in the Regulation of CD95 (Fas) Ligand Expression in Activated Human T Cells*

  • Kevin M. Latinis
    Affiliations
    Interdisciplinary Graduate Program in Immunology, University of Iowa, Iowa City, Iowa 52242
    Search for articles by this author
  • Lyse A. Norian
    Affiliations
    Interdisciplinary Graduate Program in Immunology, University of Iowa, Iowa City, Iowa 52242
    Search for articles by this author
  • Steve L. Eliason
    Affiliations
    Department of Internal Medicine, University of Iowa, Iowa City, Iowa 52242
    Search for articles by this author
  • Gary A. Koretzky
    Correspondence
    Established Investigator of the American Heart Association. To whom correspondence should be addressed: Dept. of Internal Medicine, University of Iowa College of Medicine, 540 EMRB, Iowa City, IA 52242. Tel.: 319-335-6844; Fax: 319-335-6887
    Affiliations
    Interdisciplinary Graduate Program in Immunology, University of Iowa, Iowa City, Iowa 52242

    Department of Internal Medicine, University of Iowa, Iowa City, Iowa 52242

    Departments of Physiology and Biophysics, University of Iowa, Iowa City, Iowa 52242
    Search for articles by this author
  • Author Footnotes
    * This work was supported in part by National Institutes of Health Grants PO1-CA66570 (to G. A. K.) and T32-A107485 (to L. A. N.), the University of Iowa Medical Scientist Training Program Grant 5232-GM07337 (to K. M. L.), the Arthritis Foundation (to G. A. K.), and the University of Iowa Diabetes and Endocrinology Research Center Grant 5P30-DK25295.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked “advertisement” in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Open AccessPublished:December 12, 1997DOI:https://doi.org/10.1074/jbc.272.50.31427
      Antigen receptor engagement on T lymphocytes activates transcription factors important for stimulating cytokine gene expression. This is critical for clonal expansion of antigen-specific T cells and propagation of immune responses. Additionally, under some conditions antigen receptor stimulation initiates apoptosis of T lymphocytes through the induced expression of CD95 ligand and its receptor. Here we demonstrate that the transcription factor, NFAT, which is critical for the inducible expression of many cytokine genes, also plays a critical role in the regulation of T cell receptor-mediated CD95 ligand expression. Two sites within the CD95 ligand promoter, identified through DNase I footprinting, bind NFAT proteins from nuclear extracts of activated T cells. Although both sites appear important for optimal expression of CD95 ligand in activated T cells, mutational analysis suggests that the distal NFAT site plays a more significant role. Furthermore, these sites do not appear to be required for constitutive CD95 ligand expression in Sertoli cells.
      Adaptive immune responses require the activation of T lymphocytes through antigen-specific T cell receptor (TCR)
      The abbreviations used are: TCR, T cell receptor; mAb, monoclonal antibody; IL-2, interleukin 2; PBS, phosphate-buffered saline; PMSF, phenylmethylsulfonyl fluoride; PMA, phorbol myristate acetate; DTT, dithiothreitol; CsA, cyclosporin A; EMSA, electrophoretic mobility shift assays; bp, base pair(s).
      1The abbreviations used are: TCR, T cell receptor; mAb, monoclonal antibody; IL-2, interleukin 2; PBS, phosphate-buffered saline; PMSF, phenylmethylsulfonyl fluoride; PMA, phorbol myristate acetate; DTT, dithiothreitol; CsA, cyclosporin A; EMSA, electrophoretic mobility shift assays; bp, base pair(s).
      stimulation. Signaling events initiated by TCR ligation lead to the activation of transcription factors that regulate expression of cytokine genes, such as IL-2. This is important for the clonal expansion of antigen-specific T cells and propagation of immune responses (
      • Fraser J.D.
      • Straus D.
      • Weiss A.
      ,
      • Musci M.A.
      • Latinis K.M.
      • Koretzky G.A.
      ). However, once the antigenic stimulus has been cleared, the expanded population of cells must be eliminated to prevent accumulation of excessive lymphocytes (
      • Musci M.A.
      • Latinis K.M.
      • Koretzky G.A.
      ,
      • Osborne B.A.
      ). Recently, it has been proposed that one mechanism by which this occurs is through the induced expression of CD95 ligand (
      • Alderson M.R.
      • Tough T.W.
      • Davis-Smith T.
      • Braddy S.
      • Falk B.
      • Schooley K.A.
      • Goodwin R.G.
      • Smith C.A.
      • Ramsdell F.
      • Lynch D.H.
      ,
      • Brunner T.
      • Mogil R.J.
      • LaFace D.
      • Yoo N.J.
      • Mahboubi A.
      • Echeverri F.
      • Martin S.J.
      • Force W.R.
      • Lynch D.H.
      • Ware C.F.
      • Green D.R.
      ,
      • Dhein J.
      • Walczak H.
      • Baumler C.
      • Debatin K.M.
      • Krammer P.H.
      ,
      • Ju S.T.
      • Panka D.J.
      • Cui H.
      • Ettinger R.
      • el-Khatib M.
      • Sherr D.H.
      • Stanger B.Z.
      • Marshak-Rothstein A.
      ). Once expressed, CD95 ligand engages its receptor, CD95, also expressed on the population of activated lymphocytes (
      • van Parijs L.
      • Abbas A.K.
      ). In the absence of costimulatory signals that can delay apoptosis (
      • Boise L.H.
      • Noel P.J.
      • Thompson C.B.
      ,
      • Boise L.H.
      • Minn A.J.
      • Noel P.J.
      • June C.H.
      • Accavitti M.A.
      • Lindsten T.
      • Thompson C.B.
      ,
      • Radvanyi L.G.
      • Shi Y.
      • Homayoun V.
      • Sharma A.
      • Dhala R.
      • Mills G.B.
      • Miller R.G.
      ,
      • Noel P.J.
      • Boise L.H.
      • Green J.M.
      • Thompson C.B.
      ), CD95 ligation rapidly initiates the programmed cell death machinery thus efficiently eliminating excessive activated lymphocytes (
      • van Parijs L.
      • Abbas A.K.
      ). Additionally, autoreactive T cells that are inappropriately activated in the periphery are believed to undergo apoptosis through a similar process ().
      The significance of CD95 ligand expression in the process of activation-induced cell death has been highlighted by recent studies that demonstrate that blocking CD95/CD95 ligand interactions prevents apoptosis of TCR-stimulated lymphocytes (
      • Brunner T.
      • Mogil R.J.
      • LaFace D.
      • Yoo N.J.
      • Mahboubi A.
      • Echeverri F.
      • Martin S.J.
      • Force W.R.
      • Lynch D.H.
      • Ware C.F.
      • Green D.R.
      ,
      • Ju S.T.
      • Panka D.J.
      • Cui H.
      • Ettinger R.
      • el-Khatib M.
      • Sherr D.H.
      • Stanger B.Z.
      • Marshak-Rothstein A.
      ). Interestingly, in addition to its inducible expression on activated lymphocytes, CD95 ligand is constitutively expressed on epithelial cells within the eye and Sertoli cells within the testes (
      • Bellgrau D.
      • Gold D.
      • Selawry H.
      • Moore J.
      • Franzusoff A.
      • Duke R.C.
      ,
      • Griffith T.S.
      • Brunner T.
      • Fletcher S.M.
      • Green D.R.
      • Ferguson T.A.
      ,
      • Griffith T.S.
      • Yu X.
      • Herndon J.M.
      • Green D.R.
      • Ferguson T.A.
      ). Constitutive CD95 ligand expression participates in maintenance of the “immune privileged” status of these tissues by inducing apoptosis in infiltrating, CD95-bearing, activated lymphocytes (
      • Griffith T.S.
      • Ferguson T.A.
      ). Despite improved understanding of the important physiological roles for CD95 ligand in immune privileged sites and in controlling T cell homeostasis, little is yet known about the regulation of CD95 ligand expression in these various cell types.
      In contrast, much is known about the signaling pathways that couple TCR ligation to expression of cytokine genes. Engagement of the TCR leads to rapid activation of protein tyrosine kinases of the Src and Syk families (
      • Chan A.C.
      • Shaw A.S.
      ). These protein tyrosine kinases then couple to the activation of the Ras and phospholipase Cγ1 signaling intermediates (
      • Weiss A.
      • Littman D.R.
      ). Ras activation drives signals that ultimately lead to induction of members of the AP-1 family of transcription factors, important for regulation of the IL-2 gene promoter (
      • Rothenberg E.V.
      • Ward S.B.
      ,
      • Cantrell D.
      ). Stimulation of phospholipase Cγ1 leads to the calcium-dependent activation of the serine phosphatase, calcineurin (
      • Clipstone N.A.
      • Crabtree G.R.
      ). Activated calcineurin then functions to dephosphorylate nuclear factor of activated T cell (NFAT) family members. Dephosphorylated NFAT proteins then enter the nucleus where they also serve an essential role in regulating the expression of many cytokine genes, including IL-2 (
      • Rothenberg E.V.
      • Ward S.B.
      ,
      • Rao A.
      ).
      The immunosuppressant cyclosporin A (CsA) inhibits NFAT-dependent transcriptional events by binding calcineurin and blocking its enzymatic activity, thus preventing the redistribution of NFAT to the nucleus (
      • Schreiber S.L.
      • Crabtree G.R.
      ). Previous studies demonstrated that treatment of lymphocytes with CsA also inhibits TCR-mediated CD95 ligand expression (
      • Dhein J.
      • Walczak H.
      • Baumler C.
      • Debatin K.M.
      • Krammer P.H.
      ,
      • Anel A.
      • Buferne M.
      • Boyer C.
      • Schmitt-Verhulst A.M.
      • Golstein P.
      ,
      • Brunner T.
      • Nam J.Y.
      • LaFace D.
      • Ware C.F.
      • Green D.R.
      ). Additionally, lymphocytes from mice with targeted gene disruption of the transcription factor, NFATp, display a pronounced defect in activation-induced CD95 ligand expression (
      • Hodge M.R.
      • Ranger A.M.
      • de la Brouse F.C.
      • Hoey T.
      • Grusby M.J.
      • Glimcher L.H.
      ). Furthermore, recent work from our laboratory (
      • Latinis K.M.
      • Carr L.L.
      • Peterson E.J.
      • Norian L.A.
      • Eliason S.L.
      • Koretzky G.A.
      ) utilizing a reporter construct driven by elements of the CD95 ligand promoter suggests that NFAT may play an important role in regulating CD95 ligand expression in activated T cells.
      In this study, we explore further the hypothesis that NFAT regulates CD95 ligand expression in activated lymphocytes. Using DNase I footprint analysis, we define two potential NFAT binding sites within the CD95 ligand promoter region. Both sites bind NFAT proteins independently, in an inducible and specific fashion. Yet, mutational analysis demonstrates that the distal NFAT site is more important than the proximal site for regulation of the CD95 ligand promoter in activated T cells. In contrast to the findings in T cells, experiments examining constitutively expressed CD95 ligand in Sertoli cells demonstrate that neither NFAT site is required for constitutive promoter activity in these cells.

      EXPERIMENTAL PROCEDURES

      Antibodies, Reagents, and cDNA Constructs

      The following reagents were used in this study: sodium d-luciferin (Sigma), CsA (Sigma), phorbol myristate acetate (PMA, Sigma: used for stimulations at 50 ng/ml), ionomycin (Sigma: used for stimulations at 1 μm). The following antibodies were used in this study: anti-Jurkat clonotypic TCR β chain mAb, C305 (
      • Weiss A.
      • Stobo J.D.
      ); MOPC IgG2 (Organon Teknika Corp., West Chester, PA); anti-NFATp (mAb G1-D10) and anti-NFATc (mAb 7A6) were gifts of G. Crabtree. C305 ascites was immobilized on plastic culture dishes by incubating at 37 °C with 10 μg/ml C305 in phosphate-buffered saline (PBS) for 2 h. PDT102, a pGEX3X (Pharmacia Biotech Inc.) construct containing the NFATc Rel similarity domain (amino acids 415–591), was a gift of G. Crabtree. The following reporter constructs were used in this study: CMV-βgal; CD95L-486 (
      • Latinis K.M.
      • Carr L.L.
      • Peterson E.J.
      • Norian L.A.
      • Eliason S.L.
      • Koretzky G.A.
      ); Luc-link (
      • Latinis K.M.
      • Carr L.L.
      • Peterson E.J.
      • Norian L.A.
      • Eliason S.L.
      • Koretzky G.A.
      ), Distal Mut-486 (see below), Prox. Mut-486 (see below), and Double Mut-486 (see below).

      Cell Culture and Transient Transfections

      The Jurkat human leukemic T cell line was maintained in RPMI supplemented with 10% fetal calf serum, penicillin (1000 units/ml), streptomycin (1000 units/ml), and glutamine (20 mm). The TM4 Sertoli cell line (American Type Culture Collection, Rockville, MD) was maintained in Dulbecco's modified Eagle's medium supplemented with 10% fetal calf serum, penicillin (1000 units/ml), streptomycin (1000 units/ml), and glutamine (20 mm). For transient transfections, 15 × 106 Jurkat or 20 × 106 TM4 Sertoli cells were subjected to electroporation in 400 μl of cytomix intracellular buffer (120 mm KCl, 0.15 mm CaCl2, 10 mmK2HPO4/KH2PO4 (pH 7.6), 25 mm HEPES (pH 7.6), 2 mm EGTA (pH 7.6), 5 mm MgCl2: pH adjusted with KOH and freshly added 2 mm ATP (pH 7.6) and 5 mm glutathione) with a Gene Pulser (Bio-Rad) at 250 V/960 microfarads (Jurkats) or 320 V/960 microfarads (TM4 cells). Transfection efficiencies were normalized by co-transfecting 5 μg of a CMV-βgal reporter construct followed by quantification of β-galactosidase expression using the Galacto-Light assay kit (Tropix, Bedford, MA).

      Generation of Mutant CD95 Ligand Reporter Constructs

      The distal, proximal, and double NFAT binding mutants were created using overlap extension polymerase chain reaction with the forward (F) and reverse (R) end primers (F, 5′-GAACAAGCTTAATGTATAAAAAAGCATGCAATTATAATTC-3′; R, 5′-ACATAAGCTTGGCAGCTGGTGAGTCAGGCCA-3′) and the following primers to incorporate the NFAT binding site mutations: CD95 ligand Distal Mut (F, 5′-GTGGGAATCAACTTCCAGG-3′; R, 5′-CCTGGAAGTTGATTCCCAC-3′), CD95 ligand Prox Mut (F, 5′-TAGCTATTAGATCTCTATAA-3′; R, 5′-TTATAGAGATCTAATAGCTA-3′). Wild type CD95L-486 served as a template for creation of distal and proximal NFAT mutants. The distal mutant served as a template for creation of the double mutant. All polymerase chain reaction-derived constructs were confirmed by fluorescent automated sequencing (University of Iowa DNA facility, Iowa City, IA).

      Generation of the Triplicated CD95 Ligand Promoter NFAT Reporter Constructs

      The minimal IL-2 promoter luciferase construct was created by digesting the triplicated IL-2 distal NFAT reporter with Xho-1 to drop out the IL-2 NFAT sequences followed by religation of the Xho-1 ends. The triplicated distal and proximal CD95 ligand NFAT constructs were created by annealing the following oligonucleotides containing overhanging Xho-1-compatible sites followed by cloning into the Xho-1 site of the IL-2 minimal promoter construct: distal NFAT triplication (F, 5′-TCGAGGTGGGCGGAAACTTCCAGTGGGCGGAAACTTCCAGTGGGCGGAAACTTCCAC-3′) and (R, 5′-TCGAGTGGAAGTTTCCGCCCACTGGAAGTTTCCGCCCACTGGAAGTTTCCGCCCACC-3′); proximal NFAT triplication (F, 5′-TCGAGTTAGCTATGGAAACTCTTTAGCTATGGAAACTCTTTAGCTATGGAAACTCTC-3′) and (R, 5′-TCGAGAGAGTTTCCATAGCTAAAGAGTTTCCATAGCTAAAGAGTTTCCATAGCTAAC-3′).

      Preparation of Recombinant Glutathione S-Transferase-NFATc Protein

      Transformants of the PDT102 vector were grown to OD 0.5 at 600 nm visible light and then stimulated with 0.005m isopropyl-1-thio-β-d-galactopyranoside for 1 h at room temperature with shaking. Bacteria were pelleted, resuspended in 3 ml of cold PBS, and sonicated to disrupt cell walls. After addition of 330 μl of 10% Triton (in PBS), cellular debris was pelleted. The supernatant was tumbled with glutathioneS-transferase-conjugated agarose beads for 10 min at room temperature and washed three times in 1% Triton followed by PBS. Glutathione S-transferase-NFAT protein was then eluted by tumbling beads with 1 ml of elution buffer (20 mmglutathione in 100 mm Tris (pH 8.0), 120 mmNaCl) for 10 min at 4 °C. The eluate was then dialyzed for 2 h in DB buffer (see DNase footprinting) without bovine serum albumin but supplemented with 0.3% Nonidet P-40 and 0.5 mm PMSF. Protein was quantified by the Bio-Rad protein assay.

      Preparation of Nuclear Extracts

      5 × 107Jurkat cells were left unstimulated, stimulated with immobilized C305 mAb, 50 ng/ml PMA plus 1 μm ionomycin, or with PMA plus ionomycin in the presence of 200 ng/ml CsA and then lysed in 500 μl of TLB buffer (40 mm KCl, 10 mm HEPES (pH 7.0), 3 mm MgCl2, 5% glycerol, 0.2% Nonidet P-40, 2 μg/ml leupeptin, 8 μg/ml aprotinin, 0.5 mm PMSF, and 1.0 mm DTT). Samples were centrifuged immediately at 4 °C for 2 min at 14,000 rpm. The supernatant was removed and nuclei lysed in 300 μl of NB buffer (0.42 m KCl, 20 mm HEPES (pH 7.9), 1.5 mm MgCl2, 0.2 mm EDTA, 25% glycerol, 2 μg/ml leupeptin, 8 μg/ml aprotinin, 0.5 mm PMSF, and 0.5 mm DTT) by tumbling for 30 min at 4 °C. Lysates were then dialyzed twice for 2 h in dialysis buffer (0.1 m KCl, 20 mmHEPES (pH 7.9), 0.2 mm EDTA, 20 glycerol, 0.5 mm PMSF, and 0.5 mm DTT). Protein concentrations were determined by the Bio-Rad protein assay.

      DNase I Footprint Analysis

      CD95 ligand constructs were subcloned into the HindIII site of pBluescript (Stratagene, La Jolla, CA) to allow digestion with ClaI andEcoRV to generate a 5′ overhang at the −1 end of the promoter and a blunt site at the −486 end. 25 μg of DNA was digested and gel-purified followed by incubation with 50 μCi of [α-32P]dCTP and [α-32P]dGTP (Amersham Corp.) and 5 units of Klenow enzyme for 25 min at room temperature. Probes were then purified with Stratagene push columns. DNase footprint analysis was performed by incubating 20,000 cpm of probe with indicated amounts of recombinant protein and 1.0 μg of poly(dI-dC) (Pharmacia) in 20 μl of DB buffer (10 mm Tris (pH 8.0), 15 mm HEPES (pH 7.9), 50 mm NaCl, 5 mmMgCl2, 1 mm DTT, 1 mg/ml bovine serum albumin, 5% glycerol) for 30 min on ice. Reactions were then digested with 0.75 units of DNase I diluted in DD buffer (50 mmCaCl2, 20 mm HEPES (pH 7.9)) for 5 min. Digestion was stopped by addition of 200 μl of DNase stop solution (2.5 m NH4 acetate, 25 mg/ml sheared salmon sperm DNA) and 500 μl of 100% EtOH. DNA was precipitated in a dry ice/EtOH bath for 15 min followed by centrifugation for 10 min at 4 °C. Pellets were washed in 70% EtOH, resuspended in 5 μl of formamide loading buffer, and heated at 90 °C for 5 min. Reactions were resolved on a 5% sequencing gel.

      Electrophoretic Mobility Shift Assay

      Electrophoretic mobility shift assays were performed with 4 μg of nuclear extract protein or 5 ng of recombinant protein in 50 mm KCl, 10 mm Tris (pH 7.5), 10 mm HEPES, 1.25 mm DTT, 1.1 mm EDTA, and 15% (v/v) glycerol in a volume of 20 μl. The binding reactions were incubated for 30 min at room temperature with 20,000 cpm (0.1–0.5 ng) double-stranded oligonucleotides end-labeled with [γ-32P]ATP (Amersham Corp.) using T4 polynucleotide kinase. A 1000-fold excess of unlabeled specific and nonspecific oligonucleotides were used as competitors where indicated. Supershifts were performed by addition of 1 μl of both α-NFATp and α-NFATc antibodies in the binding reactions or 1 μl MOPC as a negative control. In addition to the CD95 ligand promoter probes described in Fig. 1 B, the following double-stranded oligonucleotide probes were used in these experiments: nonspecific, 5′-TGTCGAATGCAAATCACTAGAA-3′; IL-2 dist WT, 5′-GGTCAGAAAGGAGGAAAACTGTTTCATA-3′.
      Figure thumbnail gr1
      Figure 1The CD95 ligand promoter contains two NFAT binding sites. A, DNase I footprint analysis of the CD95 ligand promoter. Indicated concentrations of recombinant NFAT proteins were incubated with 486-base pair probes corresponding to the wild type CD95 ligand promoter (lanes 1–4) or mutants containing alterations in the putative distal (lanes 5–8) or proximal (lanes 9–12) NFAT binding sites, depicted in B. Complexes were digested with DNase I and resolved on a 5% sequencing gel. Sites protected from DNase I cleavage by recombinant NFAT protein are designated NFAT distal and NFAT proximal. The putative TATA box and relative distances from the translational start site of the CD95 ligand gene are indicated at the right.Lanes 5–12 represent experiments performed in duplicate.B, schematic of the relative positions of the NFAT binding sites within the 486-base pair CD95 ligand promoter. 19-base pair DNA probes incorporating the wild type (WT) and mutant (MUT) distal and proximal NFAT sites are indicated. The predicted NFAT recognition sequences are underlined, and the 4 base pair changes accounting for each NFAT site mutation are indicated with arrows. Numbers represent the position of DNA sequences relative to the translational start site of the CD95 ligand gene. C, electrophoretic mobility shift analysis of CD95 ligand promoter NFAT sites. Recombinant NFAT protein was incubated with wild type distal (lanes 1–3) and proximal (lanes 7–9) NFAT site probes, mutant distal (lanes 4–6) and proximal (lanes 10–12) NFAT site probes, and an IL-2 promoter NFAT site probe (IL2-dist-WT, lanes 13–15), and complexes were separated on a 5% nonreducing polyacrylamide gel. No competitor (0) or a 1000-fold excess of unlabeled specific (S) or nonspecific (NS) competitors were used where indicated. The arrow indicates the migration of NFAT protein-DNA complexes.

      Luciferase Assay

      Transfected cells were treated as indicated, followed by lysis in 100 μl of harvest buffer (100 mm KPO4 (pH 7.8), 1.0 mm DTT, 1% Triton X-100). Lysates were then mixed with 100 μl of assay buffer (200 mm KPO4 (pH 7.8), 10 mm ATP, 20 mm MgCl2) followed by addition of 100 μl of 1.0 mm luciferin. Luciferase activity, expressed in arbitrary light units, was determined in triplicate for each experimental condition using a luminometer (Monolight 2010; Analytical Luminescence Laboratory, San Diego, CA).

      RESULTS

      Two Regions of the CD95 Ligand Promoter Bind NFAT Protein

      We have shown previously that a CD95 ligand reporter comprised of 486 base pairs of DNA immediately 5′ of the translational start site of the human CD95 ligand gene contains critical promoter elements for TCR-induced transcriptional activation in the Jurkat T cell line (
      • Latinis K.M.
      • Carr L.L.
      • Peterson E.J.
      • Norian L.A.
      • Eliason S.L.
      • Koretzky G.A.
      ). Additionally, this reporter reflects constitutive expression of CD95 ligand in the TM4 Sertoli cell line. This previous study also suggests that NFAT may play a role in the induced but not constitutive expression of CD95 ligand.
      To explore the role of NFAT in CD95 ligand expression further, we first attempted to map NFAT binding sites within the CD95 ligand promoter. As shown in Fig. 1 A (lanes 3 and 4), DNase I footprint analysis reveals two regions within the 486-base pair probe that are protected from enzymatic digestion through interactions with recombinant NFAT protein. We designated these regions as putative NFAT distal and NFAT proximal sites based on their location relative to the predicted TATA box.Lane 1 demonstrates that in the absence of recombinant protein both NFAT sites are DNase I-sensitive. The two sites appear to bind recombinant protein with grossly equivalent affinities as each site is partially protected from DNase I cleavage with 50 ng of protein and protected more with 500 ng. Additionally, NFAT appears to bind both DNA strands, as labeling either strand individually provides NFAT-mediated DNase I-protected sites at similar regions of the promoter (data not shown).
      Each protected site corresponds to approximately 20 base pairs within the CD95 ligand promoter. Sequence analysis reveals that both regions contain an identical GGAAA sequence that differs sufficiently from previously defined NFAT binding sites to fail recognition by a GCG computer search using the data bases described in Refs.
      • Wingender E.
      and
      • Ghosh D.
      . Many of the previously described NFAT sites within cytokine promoters bind NFAT family members cooperatively with other transcription factors (
      • Rao A.
      ). Interestingly, there are no consensus AP-1, ATF-2, Oct-1, or other recognizable transcription factor binding sites surrounding the CD95 ligand promoter NFAT elements. This suggests that the putative NFAT sites we have identified in the CD95 ligand promoter might bind NFAT proteins in the absence of these other transcription factors. In support of this, DNase footprint analysis using recombinant AP-1 protein failed to demonstrate AP-1 binding either independently or in cooperation with recombinant NFAT protein (data not shown). It is possible, of course, that other unidentified transcription factors may interact with NFAT proteins at these sites.
      To address further the specificity of NFAT binding to the two sites, each was mutated independently in the context of the 486-base pair promoter (Fig. 1 B). Both mutant probes were then assessed for their ability to bind recombinant NFAT protein in the DNase I cleavage assay. As shown in lanes 7 and 8 of Fig.1 A (representing an experiment performed with duplicate samples), mutation of the distal NFAT site disrupts the ability of NFAT protein to protect this site from DNase I cleavage. However, the non-mutated proximal site is still protected from DNase I cleavage in the presence of NFAT protein. Similarly, as shown in lanes 11 and 12, mutation of the proximal NFAT site prevents NFAT protein-mediated protection from DNase I cleavage, whereas the intact distal site still binds protein and is efficiently protected from digestion. Note that DNase I enzymatic activity is primarily targeted to purine residues, and hence both mutations alter the DNase I cleavage patterns slightly.
      To confirm the specificity of NFAT protein binding to these two sites we designed 19-mer double-stranded oligonucleotide probes corresponding to either the distal or proximal NFAT binding sites (Fig.1 B) for use in electrophoretic mobility shift assays (EMSA). Each radiolabeled probe was incubated with recombinant NFAT protein in the absence or presence of specific or nonspecific DNA competitors, and complex formation was resolved by polyacrylamide gel electrophoresis. As shown in Fig. 1 C, the wild type probe containing the distal NFAT site forms a complex with NFAT protein (lane 1) which is competed with an excess of unlabeled specific probe (lane 2) but not with an excess of a nonspecific probe (lane 3). Furthermore, a probe with a mutation in the predicted distal NFAT binding site fails completely to bind protein (lanes 4-6). Similarly, a probe containing the wild type proximal NFAT site sequence forms a complex with NFAT protein (lane 7) which is competed with excess unlabeled specific probe (lane 8) but not excess unlabeled nonspecific probe (lane 9). A mutation in the predicted proximal NFAT binding site again abolishes all protein binding (lanes 10–12). As a positive control, a probe containing a previously defined IL-2 NFAT site binds NFAT protein (lane 13) and is competed with excess unlabeled specific probe (lane 14) but not excess unlabeled nonspecific probe (lane 15). Overall these data indicate that there are at least two NFAT binding elements in the 486-bp CD95 ligand promoter region which can bind NFAT protein in a sequence-specific fashion.

      Both Proximal and Distal Sites Bind NFAT Proteins from Activated T Cell Extracts in an Inducible and Specific Fashion

      Next, to address whether NFAT proteins from activated lymphocytes can bind the putative CD95 ligand NFAT sites, distal and proximal NFAT site probes were used in EMSAs with nuclear extracts from Jurkat T cells. Nuclear extracts were prepared from cells left unstimulated or activated with immobilized anti-TCR mAb or PMA plus ionomycin (agents that bypass TCR-mediated protein tyrosine kinase events to initiate signals leading to NFAT activation). In addition, nuclear extracts were prepared from cells stimulated with PMA plus ionomycin in the presence of CsA, blocking signaling events leading to NFAT nuclear translocation. The EMSAs reveal similar results using either the distal (Fig.2, A and B) or proximal (Fig. 2, C and D) NFAT probes. Neither probe forms a specific complex with nuclear proteins from unstimulated extracts (lane 1, Fig. 2, A and C). However, activation via the TCR or with PMA plus ionomycin induces complex formation with both the distal and proximal probes (lanes 2 and 3, Fig. 2, A and C). Treatment with CsA inhibits complex formation with both distal and proximal probes (lane 4, Fig. 2, A andC).
      Figure thumbnail gr2
      Figure 2Proximal and distal CD95 ligand promoter NFAT sites bind NFAT proteins from activated T cells. EMSAs were performed with nuclear extracts prepared from Jurkat cells left unstimulated (Un) or activated with immobilized anti-TCR mAb (TCR), PMA plus ionomycin (P/I), or PMA plus ionomycin with cyclosporin A (P/I+CsA). All proximal and distal NFAT site DNA probes are illustrated in Fig. B. A and B, a radiolabeled probe containing the distal NFAT binding site was incubated with the indicated nuclear extracts (Stimulus). Bands corresponding to NFAT protein-DNA complexes, NFAT protein-DNA-mAb supershifted complexes, and nonspecific complexes are indicated witharrows. A, binding reactions were incubated in the absence of DNA or antibody competitors (NONE) or in the presence of 1000-fold excess of unlabeled nonspecific probe (Non-sp), a probe specific for the distal NFAT site (Sp-dist), a probe containing a mutation of the distal NFAT site (Mu-dist), a probe specific for the proximal NFAT site (Sp-prox), or mAbs specific for NFATp and NFATc (NFAT Ab) or isotype control mAb (Cont Ab). B, binding reactions were incubated in the presence of 1000-fold excess of unlabeled nonspecific probe (Non-sp), a probe specific for the distal NFAT site (Sp-dist), or a probe specific for the IL-2 distal NFAT site (IL-2 NF). C andD, a radiolabeled probe containing the proximal NFAT binding site was incubated with the indicated nuclear extracts (Stimulus). Bands corresponding to NFAT protein-DNA complexes, NFAT protein-DNA-mAb supershifted complexes, and nonspecific complexes are indicated with arrows. C, binding reactions were incubated in the absence of DNA or antibody competitors (NONE) or in the presence of 1000-fold excess of unlabeled nonspecific probe (Non-sp), a probe specific for the proximal NFAT site (Sp-prox), a probe containing a mutation of the proximal NFAT site (Mu-prox), a probe specific for the distal NFAT site (Sp-dist) or mAbs specific for NFATp and NFATc (NFAT Ab) or isotype control mAb (Cont Ab). D, binding reactions were incubated in the presence of 1000-fold excess of unlabeled nonspecific probe (Non-sp), a probe specific for the proximal NFAT site (Sp-prox), or a probe specific for the IL-2 distal NFAT site (IL-2 NF).
      To address the specificity of binding in these experiments both probes were mixed with nuclear extracts from PMA and ionomycin-activated Jurkat cells in the presence of various DNA competitors. An excess of unlabeled nonspecific DNA probe does not inhibit complex formation (lane 5, Fig. 2, A and C andlane 11, Fig. 2, B and D) nor do probes that incorporate mutations in the NFAT binding sites (lane 7, Fig. 2, A and C). Yet excess unlabeled probes specific for either the distal or the proximal NFAT sites compete complex formation with the labeled distal or proximal NFAT probes, respectively (lane 6, Fig. 2, A andC and lane 12, Fig. 2, B andD).
      To begin to address whether the composition of the complexes associated with the distal and proximal NFAT sites are similar, a cross competition experiment was performed. Excess unlabeled proximal probe competes complex formation with the labeled distal probe (lane 8, Fig. 2 A) and unlabeled distal probe competes complex formation with the labeled proximal probe (lane 8, Fig.2 C). This suggests that the proteins from activated nuclear extracts that form complexes with either probe are likely to have similar binding characteristics.
      To assess further whether the putative NFAT sites bind to NFAT proteins from activated Jurkat cell nuclear extracts, supershift experiments were performed with NFAT-specific antibodies. Antibodies against NFATp and NFATc (which constitute the T cell-specific isoforms of NFAT (
      • McCaffrey P.G.
      • Luo C.
      • Kerppola T.K.
      • Jain J.
      • Badalian T.M.
      • Ho A.M.
      • Burgeon E.
      • Lane W.S.
      • Lambert J.N.
      • Curran T.
      • Verdine G.L.
      • Rao A.
      • Hogan P.G.
      ,
      • Ho S.
      • Timmerman L.
      • Northrop J.
      • Crabtree G.R.
      )) were incubated with nuclear extracts from PMA and ionomycin-activated Jurkat cells in the presence of labeled distal and proximal NFAT probes. In both instances the specific complexes are supershifted (lane 9, Fig. 2, A andC), indicating that each probe binds NFAT proteins from activated nuclear extracts. A nonspecific isotype control antibody does not induce a supershift (lane 10, Fig. 2, A andC). Interestingly, in contrast to what has been shown for the IL-2 NFAT sites, antibodies specific for AP-1 transcription factor components fail to supershift complexes formed with distal and proximal CD95 ligand NFAT probes, whereas supershift formation is detected with a control probe containing an AP-1 site (data not shown).
      Finally, we examined whether the specificities of NFAT complex formation with the CD95 ligand NFAT sites are similar to that of an NFAT site from the IL-2 promoter. Complex formation with either labeled distal or proximal CD95 ligand NFAT probe is competed efficiently with a probe containing a canonical NFAT binding site derived from the IL-2 gene promoter (lane 13, Fig. 2, B andD). This suggests that NFAT protein binding specificities for each site are similar. Collectively, these results indicate that both the distal and proximal CD95 ligand promoter NFAT sites are capable of binding nuclear NFAT proteins from T cells in an inducible and specific fashion.

      Both Proximal and Distal CD95 Ligand Promoter NFAT Sites Can Function Independently to Support Transcriptional Activation in T Cells

      Having determined that both the distal and proximal CD95 ligand promoter NFAT sites are capable of binding NFAT proteins from activated lymphocytes, experiments were designed to test whether these sites are capable of activating transcription in cells. We created reporter constructs containing triplicate copies of the distal NFAT or the proximal NFAT site placed upstream of the previously defined IL-2 minimal promoter. The reporters were transfected transiently into Jurkat cells and stimulated with immobilized α-TCR antibody, alone or in the presence of CsA. As shown in Fig.3, the minimal IL-2 promoter exhibits little reporter activity in TCR-stimulated cells. In contrast, reporter constructs driven by either the distal or proximal NFAT sites are activated substantially by TCR engagement relative to unstimulated controls. As predicted, the inducible response for both triplicated reporters is blocked completely by the addition of CsA during TCR stimulation, suggesting that the observed reporter activity depends on NFAT nuclear translocation. These results indicate that each NFAT binding site within the CD95 ligand promoter region can activate transcription independently. Surprisingly, in contrast to studies that demonstrate the capacity of calcium ionophore stimulation to partially activate the full-length, 486-bp CD95 ligand reporter (
      • Latinis K.M.
      • Carr L.L.
      • Peterson E.J.
      • Norian L.A.
      • Eliason S.L.
      • Koretzky G.A.
      ), the triplicated reporters are not activated by calcium signals alone (data not shown). Despite our observations that these NFAT sites do not cooperate with AP-1 factors, this result suggests that their regulation may require other, as yet unidentified, factors. Furthermore, the calcium-responsive nature of the full-length reporter may involve other calcium-dependent transcriptional regulators in addition to NFAT.
      Figure thumbnail gr3
      Figure 3Triplicated distal and proximal NFAT sites are independently capable of driving transcription in activated T cells. Jurkat T cells were transfected with 40 μg of reporter constructs containing the IL-2 minimal promoter alone (Min Promoter) or with triplicated copies of the distal (3X-dist NFAT) or proximal (3X-prox NFAT) NFAT sites. Transfectants were left unstimulated (NS) or stimulated for 16 h with immobilized anti-TCR mAb (TCR) or anti-TCR mAb plus cyclosporin A (TCR+CsA). Cells were lysed and assayed for luciferase activity. Data are expressed as arbitrary luciferase light units and are representative of three independent experiments. Error bars represent the S.D. of triplicate samples.

      Mutation of the Distal NFAT Site Has a More Pronounced Effect on CD95 Ligand Promoter Activity in T Cells Than Does Mutation of the Proximal Site

      We next addressed the functional importance of the two NFAT sites for TCR-mediated CD95 ligand expression. Each site was mutated independently or together in the context of the full-length, 486-bp CD95 ligand reporter. The mutant constructs incorporate the sequence alterations shown in Fig. 1 B which prevent NFAT protein binding. Jurkat cells were transfected with the wild type reporter or one of the mutant reporters and then left unstimulated or stimulated with immobilized anti-TCR mAb or anti-TCR mAb plus CsA. As shown in Fig. 4 A, engagement of the TCR on cells transfected with the wild type reporter results in a 24-fold increase in luciferase activity relative to unstimulated cells or cells stimulated in the presence of CsA. Shown also, in agreement with prior studies (
      • Latinis K.M.
      • Carr L.L.
      • Peterson E.J.
      • Norian L.A.
      • Eliason S.L.
      • Koretzky G.A.
      ), the distal NFAT site mutant reporter exhibits markedly diminished background luciferase expression, and TCR stimulation is much less effective at inducing luciferase activity in cells transfected with this reporter. In contrast, mutation of the proximal NFAT site appears to have a less dramatic effect on activation of the CD95 ligand promoter. TCR stimulation of cells transfected with this reporter still results in a 19-fold increase in luciferase activity over unstimulated cells. However, in each of four independent experiments, the proximal NFAT binding site mutant reporter is significantly less inducible than the wild type reporter. Similar to the wild type reporter, this activity is inhibited completely by CsA. As shown in Fig. 4 B, a reporter containing both NFAT site mutations also exhibits minimal luciferase production in TCR-activated Jurkat cells, similar to the effect of the distal site mutation. Collectively, these results indicate that both NFAT sites participate in the maximal activation of the CD95 ligand reporter; however, the distal site contribution appears greater.
      Figure thumbnail gr4
      Figure 4NFAT sites are important for optimal CD95 ligand promoter activation in T cells. A, Jurkat cells were transfected with 70 μg of the wild type 486-bp CD95 ligand reporter (CD95L-486) or reporters containing mutations in the distal (Distal Mut-486) or proximal (Prox. Mut-486) NFAT sites. Transfectants were left unstimulated (NS) or stimulated for 16 h with immobilized anti-TCR mAb (TCR) or anti-TCR mAb plus cyclosporin A (TCR+CsA). Cells were lysed and assayed for luciferase activity. The relative increase of TCR-induced activity over unstimulated controls are 24-, 7-, and 19-fold for CD95L-486, distal mut-486, and prox. mut-486, respectively. Data are expressed as arbitrary luciferase light units and are representative of four independent experiments. Error bars represent the S.D. of triplicate samples. B, Jurkat cells were transfected with 70 μg of the wild type 486-bp CD95 ligand reporter (CD95L-486) or a reporter containing mutations in both the distal and proximal NFAT sites (Double Mut). Transfectants were left unstimulated (NS) or stimulated for 16 h with immobilized anti-TCR mAb (TCR) or anti-TCR mAb plus cyclosporin A (TCR+CsA). Cells were lysed and assayed for luciferase activity. The relative increase of TCR-induced activity over unstimulated controls are 21- and 10-fold for CD95L-486 and Double Mut-486, respectively. Data are expressed as arbitrary luciferase light units and are representative of four independent experiments. Error bars represent the S.D. of triplicate samples.
      Interestingly, truncation mutants of the CD95 ligand promoter behave differently from the NFAT site-specific mutant constructs. When the distal NFAT site is eliminated by truncating the promoter 3′ to this site, the resulting reporter is still activated to approximately 50% of the level seen with the full-length reporter (data not shown). In contrast, as shown in Fig. 4 A, the distal site mutant consistently provides a more pronounced diminution in reporter activity. One explanation for this discrepancy is that a transcriptional repressor site may exist in the region deleted by the truncations. This model predicts that in the absence of the repressor, other factor binding sites within the remaining promoter region may be capable of activating transcription. In contrast, the repressor would still function in the distal NFAT site mutant reporter, thus limiting the degree of reporter activation. Efforts are currently underway to elucidate the mechanism for this difference between the truncation and point mutant reporters.

      Individual NFAT Sites Are Not Essential for Constitutive CD95 Ligand Expression in Sertoli Cells

      Next, to address the role of the distal and proximal NFAT sites for constitutive CD95 ligand expression, we performed experiments using a Sertoli cell line which, as previously reported, constitutively expresses CD95 ligand transcripts (
      • Latinis K.M.
      • Carr L.L.
      • Peterson E.J.
      • Norian L.A.
      • Eliason S.L.
      • Koretzky G.A.
      ). By utilizing cytotoxicity assays with CD95-sensitive target cells, we confirmed that this cell line expresses functional CD95 ligand (data not shown). This Sertoli line was then transfected with either the wild type CD95 ligand reporter, a reporter containing the distal NFAT site mutation, a reporter containing the proximal NFAT site mutation, or a control luciferase reporter lacking a promoter. Cells were cultured for 72 h post-transfection and then assayed for luciferase activity. As shown in Fig.5, the wild type reporter as well as both reporters containing NFAT site mutations exhibit high levels of luciferase activity relative to the control reporter, indicating high basal activity for each. The double NFAT site mutant reporter also exhibits high basal levels of reporter activity relative to controls (data not shown). However, in three independent experiments there is somewhat less reporter activity with the double NFAT mutant than with the wild type construct. The mechanism for this reduced activity is currently under investigation. Yet, together with the previous observation that cyclosporin A does not inhibit constitutive CD95 ligand reporter activity in Sertoli cells (
      • Latinis K.M.
      • Carr L.L.
      • Peterson E.J.
      • Norian L.A.
      • Eliason S.L.
      • Koretzky G.A.
      ), these results suggest that the NFAT sites of the CD95 ligand promoter do not function independently as positive regulators for CD95 ligand expression in this Sertoli cell line.
      Figure thumbnail gr5
      Figure 5NFAT sites are not required for constitutive CD95 ligand reporter activity in Sertoli cells. TM4 Sertoli cells were transfected with 70 μg of the wild type 486-bp CD95 ligand reporter (CD95L-486), reporters containing mutations in the distal (Distal Mutant) or proximal (Proximal Mutant) NFAT sites, or a promoterless luciferase reporter (Luc-Link). Transfectants were cultured for 72 h in growth media, lysed, and then assayed for luciferase activity. Data are expressed as arbitrary luciferase light units and are representative of three independent experiments. Error bars represent the standard deviation of triplicate samples.

      DISCUSSION

      The biological importance of CD95 ligand has been highlighted recently by work demonstrating its critical role in both activation-induced cell death in T cells (
      • Alderson M.R.
      • Tough T.W.
      • Davis-Smith T.
      • Braddy S.
      • Falk B.
      • Schooley K.A.
      • Goodwin R.G.
      • Smith C.A.
      • Ramsdell F.
      • Lynch D.H.
      ,
      • Brunner T.
      • Mogil R.J.
      • LaFace D.
      • Yoo N.J.
      • Mahboubi A.
      • Echeverri F.
      • Martin S.J.
      • Force W.R.
      • Lynch D.H.
      • Ware C.F.
      • Green D.R.
      ,
      • Dhein J.
      • Walczak H.
      • Baumler C.
      • Debatin K.M.
      • Krammer P.H.
      ,
      • Ju S.T.
      • Panka D.J.
      • Cui H.
      • Ettinger R.
      • el-Khatib M.
      • Sherr D.H.
      • Stanger B.Z.
      • Marshak-Rothstein A.
      ,
      • Anel A.
      • Buferne M.
      • Boyer C.
      • Schmitt-Verhulst A.M.
      • Golstein P.
      ) and in the maintenance of immune privilege within certain tissues (
      • Bellgrau D.
      • Gold D.
      • Selawry H.
      • Moore J.
      • Franzusoff A.
      • Duke R.C.
      ,
      • Griffith T.S.
      • Brunner T.
      • Fletcher S.M.
      • Green D.R.
      • Ferguson T.A.
      ,
      • Griffith T.S.
      • Yu X.
      • Herndon J.M.
      • Green D.R.
      • Ferguson T.A.
      ,
      • Griffith T.S.
      • Ferguson T.A.
      ). However, relatively little is known about factors that control inducible expression of CD95 ligand in lymphocytes or constitutive expression in epithelial cells of the eye or Sertoli cells within the testes. Only recently, using somatic cell mutants, pharmacologic agents and antisense oligonucleotides, or a reporter system which reflects endogenous gene expression, have studies begun to address the role of intracellular signaling pathways that lead to the transcriptional activation of the CD95 ligand gene (
      • Latinis K.M.
      • Carr L.L.
      • Peterson E.J.
      • Norian L.A.
      • Eliason S.L.
      • Koretzky G.A.
      ,
      • Oyaizu N.
      • Than S.
      • McCloskey T.W.
      • Pahwa S.
      ,
      • Ivanov V.N.
      • Lee R.R.
      • Podack E.R.
      • Malek T.R.
      ).
      Previous studies have demonstrated that CD95 ligand expression in TCR-stimulated lymphocytes can be blocked by CsA (
      • Dhein J.
      • Walczak H.
      • Baumler C.
      • Debatin K.M.
      • Krammer P.H.
      ,
      • Anel A.
      • Buferne M.
      • Boyer C.
      • Schmitt-Verhulst A.M.
      • Golstein P.
      ,
      • Brunner T.
      • Nam J.Y.
      • LaFace D.
      • Ware C.F.
      • Green D.R.
      ). Furthermore, mice deficient in the transcription factor NFATp display a pronounced defect in the ability to produce CD95 ligand transcripts following T cell activation (
      • Hodge M.R.
      • Ranger A.M.
      • de la Brouse F.C.
      • Hoey T.
      • Grusby M.J.
      • Glimcher L.H.
      ). Interestingly, these mice exhibit a lymphoproliferative phenotype similar to that seen in other murine lines defective in pathways leading to activation-induced cell death (
      • Takahashi T.
      • Tanaka M.
      • Brannan C.I.
      • Jenkins N.A.
      • Copeland N.G.
      • Suda T.
      • Nagata S.
      ,
      • Watanabe-Fukunaga R.
      • Brannan C.I.
      • Copeland N.G.
      • Jenkins N.A.
      • Nagata S.
      ). More recently, work from our laboratory utilizing a CD95 ligand reporter suggests that NFAT may be important for the regulation of CD95 ligand expression in activated T cells (
      • Latinis K.M.
      • Carr L.L.
      • Peterson E.J.
      • Norian L.A.
      • Eliason S.L.
      • Koretzky G.A.
      ).
      In this study we explored the role played by NFAT in the regulation of activation-induced CD95 ligand expression in T cells. Through DNase I footprinting and gel shift analysis, we identified two NFAT binding sites within the first 486 base pairs of the CD95 ligand promoter. When analyzed independently each site can facilitate transcription through a calcineurin-dependent mechanism. However, the distal site plays a more important role in driving TCR-mediated expression of CD95 ligand. These data support the notion that NFAT participates in the regulation of CD95 ligand expression in activated T cells. It is important to note, however, that relative to reporter activity in unstimulated cells, neither NFAT single mutant nor the double mutant completely blocks TCR inducibility, suggesting that other regions of the promoter likely contribute to the inducible expression of CD95 ligand in T cells.
      Much of what is known about the function of NFAT proteins has been derived from analysis of cytokine gene promoters in lymphocytes (
      • Rao A.
      ). To date, four isoforms of NFAT proteins have been cloned (
      • McCaffrey P.G.
      • Luo C.
      • Kerppola T.K.
      • Jain J.
      • Badalian T.M.
      • Ho A.M.
      • Burgeon E.
      • Lane W.S.
      • Lambert J.N.
      • Curran T.
      • Verdine G.L.
      • Rao A.
      • Hogan P.G.
      ,
      • Ho S.
      • Timmerman L.
      • Northrop J.
      • Crabtree G.R.
      ,
      • Hoey T.
      • Sun Y.L.
      • Williamson K.
      • Xu X.
      ,
      • Masuda E.S.
      • Naito Y.
      • Tokumitsu H.
      • Campbell D.
      • Saito F.
      • Hannum C.
      • Arai K.
      • Arai N.
      ,
      • Ho S.N.
      • Thomas D.J.
      • Timmerman L.A.
      • Li X.
      • Francke U.
      • Crabtree G.R.
      ). Interestingly, each isoform binds to similar DNA sequences via an internal region of the protein which is homologous to the Rel family of transcription factors (
      • Jain J.
      • Burgeon E.
      • Badalian T.M.
      • Hogan P.G.
      • Rao A.
      ). NFATp and NFATc are the predominant isoforms expressed in mature lymphocytes (
      • McCaffrey P.G.
      • Luo C.
      • Kerppola T.K.
      • Jain J.
      • Badalian T.M.
      • Ho A.M.
      • Burgeon E.
      • Lane W.S.
      • Lambert J.N.
      • Curran T.
      • Verdine G.L.
      • Rao A.
      • Hogan P.G.
      ,
      • Ho S.
      • Timmerman L.
      • Northrop J.
      • Crabtree G.R.
      ). They function as key regulators of IL-2, IL-3, granulocyte monocyte colony-stimulating factor, IL-4, interferon-γ, and tumor necrosis factor-α expression (
      • Rao A.
      ). Furthermore, TCR-mediated nuclear translocation of each isoform is inhibitable with CsA.
      Studies of the IL-2 promoter indicate that as many as five NFAT binding sites participate in the regulation of this gene (
      • Rothenberg E.V.
      • Ward S.B.
      ,
      • Rooney J.W.
      • Sun Y.L.
      • Glimcher L.H.
      • Hoey T.
      ). Recent mutational analysis indicates that all five NFAT sites are essential for optimal TCR-mediated activation of this promoter (
      • Rooney J.W.
      • Sun Y.L.
      • Glimcher L.H.
      • Hoey T.
      ). Thus NFAT acts as a key transcription factor regulating cytokine gene expression critical for the clonal expansion of lymphocytes. Our results indicate that NFAT proteins are also critical for the expression of CD95 ligand, a molecule whose induction is important for triggering apoptosis in activated T cells. Similarly, other TCR-mediated signaling events, such as Ras activation, have been shown to participate in both IL-2 induction (
      • Rayter S.I.
      • Woodrow M.
      • Lucas S.C.
      • Cantrell D.A.
      • Downward J.
      ,
      • Pastor M.I.
      • Woodrow M.
      • Cantrell D.
      ) as well as CD95 ligand expression (
      • Latinis K.M.
      • Carr L.L.
      • Peterson E.J.
      • Norian L.A.
      • Eliason S.L.
      • Koretzky G.A.
      ). Thus, it appears that many of the same signaling events are important for induction of cellular activation and termination of immune responses. Whether TCR engagement leads to proliferation or cell death may in fact depend on signals delivered via receptors other than the TCR. Recent work from numerous laboratories has focused on signaling events initiated by CD28 ligation which lead to protection from apoptosis (
      • Boise L.H.
      • Noel P.J.
      • Thompson C.B.
      ,
      • Boise L.H.
      • Minn A.J.
      • Noel P.J.
      • June C.H.
      • Accavitti M.A.
      • Lindsten T.
      • Thompson C.B.
      ,
      • Radvanyi L.G.
      • Shi Y.
      • Homayoun V.
      • Sharma A.
      • Dhala R.
      • Mills G.B.
      • Miller R.G.
      ,
      • Noel P.J.
      • Boise L.H.
      • Green J.M.
      • Thompson C.B.
      ). Although inspection of the CD95 ligand promoter does not suggest the presence of consensus CD28 response elements, further studies are needed to determine whether co-receptors play a role in the regulation of CD95 ligand expression.
      This study additionally supports the existence of NFAT binding sites that appear to function independently of AP-1 cofactors. Previous studies of numerous cytokine gene promoters have described NFAT binding sites that couple with additional transcription factor binding sites immediately 3′ to the NFAT sequence (
      • Rao A.
      ). For instance, several NFAT sites within the IL-2 promoter are activated by both NFAT and AP-1 factors binding cooperatively (
      • Rao A.
      ). This likely explains the requirement for both calcium signals and Ras-dependent signals for activation of these sites, as increases in calcium lead to calcineurin-dependent nuclear translocation of NFAT proteins, and Ras activation leads to stimulation of AP-1 factors. In contrast, the CD95 ligand promoter NFAT sites we have found, as well as recently described NFAT binding sites within the TNF-α promoter (
      • Tsai E.Y.
      • Yie J.
      • Thanos D.
      • Goldfeld A.E.
      ) and an enhancer region of the IL-3 gene (
      • Duncliffe K.N.
      • Bert A.G.
      • Vadas M.A.
      • Cockerill P.N.
      ), seem to function without cooperative assistance from AP-1 factors. These NFAT sites do not possess surrounding identifiable transcription factor binding sites. Furthermore, the purine-rich regions that dictate NFAT binding in the CD95 ligand promoter as well as the NFAT sites of the tumor necrosis factor-α promoter and IL-3 enhancer consist of a GGAAA core DNA sequence. In contrast, the previously defined human IL-2 NFAT/AP-1 consensus sequence is GGAAAAACTGTTTCA (
      • Rao A.
      ).
      It is important to note that previous work has shown that Ras-dependent signals are also important for regulating CD95 ligand expression in activated T cells (
      • Latinis K.M.
      • Carr L.L.
      • Peterson E.J.
      • Norian L.A.
      • Eliason S.L.
      • Koretzky G.A.
      ). Since these signals do not seem to influence AP-1 cooperative binding of the CD95 ligand promoter NFAT sites, it is likely that other regions of the CD95 ligand promoter contain transcription factor binding sites that are dependent on Ras-mediated signals. Further promoter analysis directed at identifying these sites should provide more insight into the inducible regulation of CD95 ligand expression in activated T cells.
      Finally, this study begins to address the regulation of CD95 ligand expression in cells that constitutively express this molecule. Our data suggest that NFAT sites in the CD95 ligand promoter that are critical for activation-induced expression in T cells are not required for constitutive expression of CD95 ligand in Sertoli cells. In agreement with this, NFAT factors have not been described to play a major role in the regulation of constitutively expressed genes in cells outside of the immune system. It is interesting to speculate, however, that certain cells contained in immune privileged tissues of the body possess transcriptional regulatory factors that are responsible for the constitutive expression of CD95 ligand. Identification of these factors could provide insight into the regulation of immune privilege status within these tissues.

      Acknowledgments

      We thank Dr. Erik Peterson for critical review of the manuscript and Dr. Gerald Crabtree for the generous gifts of reagents.

      REFERENCES

        • Fraser J.D.
        • Straus D.
        • Weiss A.
        Immunol. Today. 1993; 14: 357-362
        • Musci M.A.
        • Latinis K.M.
        • Koretzky G.A.
        Clin. Immunol. Immunopathol. 1997; 83: 205-222
        • Osborne B.A.
        Curr. Opin. Immunol. 1996; 8: 245-254
        • Alderson M.R.
        • Tough T.W.
        • Davis-Smith T.
        • Braddy S.
        • Falk B.
        • Schooley K.A.
        • Goodwin R.G.
        • Smith C.A.
        • Ramsdell F.
        • Lynch D.H.
        J. Exp. Med. 1995; 181: 71-77
        • Brunner T.
        • Mogil R.J.
        • LaFace D.
        • Yoo N.J.
        • Mahboubi A.
        • Echeverri F.
        • Martin S.J.
        • Force W.R.
        • Lynch D.H.
        • Ware C.F.
        • Green D.R.
        Nature. 1995; 373: 441-444
        • Dhein J.
        • Walczak H.
        • Baumler C.
        • Debatin K.M.
        • Krammer P.H.
        Nature. 1995; 373: 438-441
        • Ju S.T.
        • Panka D.J.
        • Cui H.
        • Ettinger R.
        • el-Khatib M.
        • Sherr D.H.
        • Stanger B.Z.
        • Marshak-Rothstein A.
        Nature. 1995; 373: 444-448
        • van Parijs L.
        • Abbas A.K.
        Curr. Opin. Immunol. 1996; 8: 355-361
        • Boise L.H.
        • Noel P.J.
        • Thompson C.B.
        Curr. Opin. Immunol. 1995; 7: 620-625
        • Boise L.H.
        • Minn A.J.
        • Noel P.J.
        • June C.H.
        • Accavitti M.A.
        • Lindsten T.
        • Thompson C.B.
        Immunity. 1995; 3: 87-98
        • Radvanyi L.G.
        • Shi Y.
        • Homayoun V.
        • Sharma A.
        • Dhala R.
        • Mills G.B.
        • Miller R.G.
        J. Immunol. 1996; 156: 1788-1798
        • Noel P.J.
        • Boise L.H.
        • Green J.M.
        • Thompson C.B.
        J. Immunol. 1996; 157: 636-642
        • Abbas A.K.
        Cell. 1996; 84: 655-657
        • Bellgrau D.
        • Gold D.
        • Selawry H.
        • Moore J.
        • Franzusoff A.
        • Duke R.C.
        Nature. 1995; 377: 630-632
        • Griffith T.S.
        • Brunner T.
        • Fletcher S.M.
        • Green D.R.
        • Ferguson T.A.
        Science. 1995; 270: 1189-1192
        • Griffith T.S.
        • Yu X.
        • Herndon J.M.
        • Green D.R.
        • Ferguson T.A.
        Immunity. 1996; 5: 7-16
        • Griffith T.S.
        • Ferguson T.A.
        Immunol. Today. 1997; 18: 240-244
        • Chan A.C.
        • Shaw A.S.
        Curr. Opin. Immunol. 1996; 8: 394-401
        • Weiss A.
        • Littman D.R.
        Cell. 1994; 76: 263-274
        • Rothenberg E.V.
        • Ward S.B.
        Proc. Natl. Acad. Sci. U. S. A. 1996; 93: 9358-9365
        • Cantrell D.
        Annu. Rev. Immunol. 1996; 14: 259-274
        • Clipstone N.A.
        • Crabtree G.R.
        Nature. 1992; 357: 695-697
        • Rao A.
        Immunol. Today. 1994; 15: 274-281
        • Schreiber S.L.
        • Crabtree G.R.
        Immunol. Today. 1992; 13: 136-142
        • Anel A.
        • Buferne M.
        • Boyer C.
        • Schmitt-Verhulst A.M.
        • Golstein P.
        Eur. J. Immunol. 1994; 24: 2469-2476
        • Brunner T.
        • Nam J.Y.
        • LaFace D.
        • Ware C.F.
        • Green D.R.
        Int. Immunol. 1996; 8: 1017-1026
        • Hodge M.R.
        • Ranger A.M.
        • de la Brouse F.C.
        • Hoey T.
        • Grusby M.J.
        • Glimcher L.H.
        Immunity. 1996; 4: 397-405
        • Latinis K.M.
        • Carr L.L.
        • Peterson E.J.
        • Norian L.A.
        • Eliason S.L.
        • Koretzky G.A.
        J. Immunol. 1997; 158: 4602-4611
        • Weiss A.
        • Stobo J.D.
        J. Exp. Med. 1984; 160: 1284-1299
        • Wingender E.
        J. Biotech. 1994; 35: 273-280
        • Ghosh D.
        Nucleic Acids Res. 1993; 21: 3117-3118
        • McCaffrey P.G.
        • Luo C.
        • Kerppola T.K.
        • Jain J.
        • Badalian T.M.
        • Ho A.M.
        • Burgeon E.
        • Lane W.S.
        • Lambert J.N.
        • Curran T.
        • Verdine G.L.
        • Rao A.
        • Hogan P.G.
        Science. 1993; 262: 750-754
        • Ho S.
        • Timmerman L.
        • Northrop J.
        • Crabtree G.R.
        Adv. Exp. Med. Biol. 1994; 365: 167-173
        • Oyaizu N.
        • Than S.
        • McCloskey T.W.
        • Pahwa S.
        Biochem. Biophys. Res. Commun. 1995; 213: 994-1001
        • Ivanov V.N.
        • Lee R.R.
        • Podack E.R.
        • Malek T.R.
        Oncogene. 1997; 14: 2455-2464
        • Takahashi T.
        • Tanaka M.
        • Brannan C.I.
        • Jenkins N.A.
        • Copeland N.G.
        • Suda T.
        • Nagata S.
        Cell. 1994; 76: 969-976
        • Watanabe-Fukunaga R.
        • Brannan C.I.
        • Copeland N.G.
        • Jenkins N.A.
        • Nagata S.
        Nature. 1992; 356: 314-317
        • Hoey T.
        • Sun Y.L.
        • Williamson K.
        • Xu X.
        Immunity. 1995; 2: 461-472
        • Masuda E.S.
        • Naito Y.
        • Tokumitsu H.
        • Campbell D.
        • Saito F.
        • Hannum C.
        • Arai K.
        • Arai N.
        Mol. Cell. Biol. 1995; 15: 2697-2706
        • Ho S.N.
        • Thomas D.J.
        • Timmerman L.A.
        • Li X.
        • Francke U.
        • Crabtree G.R.
        J. Biol. Chem. 1995; 270: 19898-19907
        • Jain J.
        • Burgeon E.
        • Badalian T.M.
        • Hogan P.G.
        • Rao A.
        J. Biol. Chem. 1995; 270: 4138-4145
        • Rooney J.W.
        • Sun Y.L.
        • Glimcher L.H.
        • Hoey T.
        Mol. Cell. Biol. 1995; 15: 6299-6310
        • Rayter S.I.
        • Woodrow M.
        • Lucas S.C.
        • Cantrell D.A.
        • Downward J.
        EMBO J. 1992; 11: 4549-4556
        • Pastor M.I.
        • Woodrow M.
        • Cantrell D.
        Cancer Surv. 1995; 22: 75-83
        • Tsai E.Y.
        • Yie J.
        • Thanos D.
        • Goldfeld A.E.
        Mol. Cell. Biol. 1996; 16: 5232-5244
        • Duncliffe K.N.
        • Bert A.G.
        • Vadas M.A.
        • Cockerill P.N.
        Immunity. 1997; 6: 175-185