©1995 by The American Society for Biochemistry and Molecular Biology, Inc.
Triggering of the Human Interleukin-6 Gene by Interferon- and Tumor Necrosis Factor- in Monocytic Cells Involves Cooperation between Interferon Regulatory Factor-1, NFB, and Sp1 Transcription Factors (*)

(Received for publication, May 22, 1995; and in revised form, September 1, 1995)

Josiane Sancéau (1)(§) Tsuneyasu Kaisho (2) Toshio Hirano (2) Juana Wietzerbin (1)

From the  (1)From INSERM, U365, ``Interferons et Cytokines,'' Institut Curie, Section de Recherches, 26, rue d'Ulm, 75231 Paris, France and the (2)Biomedical Research Center, Osaka University Medical School, Division of Molecular Oncology, 2-2 Yamada-oka, Suita, Osaka 565, Japan

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

We investigated the molecular basis of the synergistic induction by interferon- (IFN-)/tumor necrosis factor-alpha (TNF- alpha) of human interleukin-6 (IL-6) gene in THP-1 monocytic cells, and compared it with the basis of this induction by lipopolysaccharide (LPS). Functional studies with IL-6 promoter demonstrated that three regions are the targets of the IFN- and/or TNF-alpha action, whereas only one of these regions seemed to be implicated in LPS activation. The three regions concerned are: 1) a region between -73 and -36, which is the minimal element inducible by LPS or TNF-alpha; 2) an element located between -181 and -73, which appeared to regulate the response to IFN- and TNF-alpha negatively; and 3) a distal element upstream of -224, which was inducible by IFN- alone. LPS signaling was found to involve NFkappaB activation by the p50/p65 heterodimers. Synergistic induction of the IL-6 gene by IFN- and TNF-alpha, in monocytic cells, involved cooperation between the IRF-1 and NFkappaB p65 homodimers with concomitant removal of the negative effect of the retinoblastoma control element present in the IL-6 promoter. This removal occurred by activation of the constitutive Sp1 factor, whose increased binding activity and phosphorylation were mediated by IFN-.


INTRODUCTION

IL-6^1 is a multifunctional cytokine involved in controlling many cell functions, including antibody synthesis by B cells, T cell cytotoxicity, stem cell differentiation, and induction of acute phase proteins. IL-6 is produced in response to a variety of noxious stimuli, including viral and bacterial infections(1, 2, 3, 4) . Deficient regulation of the IL-6 gene is involved in the pathogenesis of autoimmune diseases and affects normal and leukemic hematopoiesis(4, 5, 6, 7, 8, 9) . Recent studies demonstrated the presence of a defect in IL-6 production in Fanconi's anemia(10, 11) , suggesting that is partly responsible for the altered hemopoiesis in Fanconi's anemia patients.

The transcriptional regulatory elements present in the 5`-flanking region of the human IL-6 gene have been studied by several laboratories. Various elements responsible for IL-6 gene induction have been identified, including phorbol 12-myristate 13-acetate, cAMP, NFkappaB, NF-IL-6, and multiple cytokine-responsive elements(3, 4, 12, 13, 14, 15, 16) . Tumor suppressor gene products p53 and pRB have been reported to suppress IL-6 promoter activity(17) .

Different laboratories, including ours, showed that there are cell type- dependent differences in the mechanism and transcription factors involved in IL-6 gene induction. Thus, TNF-alpha induced IL-6 in a variety of cell types(18, 19, 20, 21) , but it failed to do so in monocytes(2, 3, 20) . We have shown that IFN- is an essential co-signal for TNF-alpha in the induction of IL-6 in monocytic THP-1 cells(22) .

The role of IL-6 in the immune response, acute phase reaction, and hematopoiesis, and the fact that monocytic cells appeared to be one of the major physiological sources of this cytokine, prompted us to analyze the molecular mechanism responsible for its induction in this cell type.

Although the mechanism of transcriptional activation mediated by different inducers in several cell types has been extensively studied, the mechanism responsible for synergistic IL-6 gene induction by IFN- and TNF-alpha in monocytic cells has still not been identified.

We postulated that both IFN- and TNF-alpha activate transcription factors, which should act simultaneously to induce IL-6 gene expression. This hypothesis was supported by our previous finding that sequential stimulation with IFN-, followed by TNF-alpha stimulation, did not lead to IL-6 mRNA induction(22) . This implied that IFN- and TNF-alpha induced or activated different transiently expressed components, which must act together in cooperation to trigger IL-6 gene expression.

It has been suggested that the induction of NFkappaB binding activity by TNF-alpha contributes to the activation of the IL-6 promoter in some cell lines, including monocytic cells(3, 18, 19, 20) . The NFkappaB/Rel family of transcription factors consists of at least five proteins, including p65 (Rel A), p50, c-Rel, and p52, which are related to each other through an N-terminal stretch of 300 amino acids called the Rel homology domain. DNA binding occurs through dimerization of the family members, resulting in numerous homo- and heterodimeric combinations of NFkappaB/Rel proteins. The C-terminal region of p65, c-Rel, and Rel-B harbor a transcriptional activation domain, and the in vivo transcriptional activity is attributed to the p65-, c-Rel-, and Rel-B-containing dimers(23) .

The elements involved in the IFN--mediated induction of IL-6 expression are not known. The binding of IFNalpha/beta to their specific receptors rapidly activates a latent cytoplasmic transcription factor, ISGF3 (interferon-stimulated gene factor 3). ISGF3 is transiently activated and has been shown to stimulate ISRE-dependent transcription(24, 25, 26, 27) . Other regulatory factors, including interferon-regulatory factor 1 (IRF-1) and IRF-2, have also been shown to be involved in the regulation of the IFN system. IRF-1 and IRF-2 bind to similar cis elements within type I IFN and IFN-inducible genes. IRF-1 functions as a transcriptional activator, while IRF-2 represses IRF-1 function(28, 29, 30, 31, 32, 33) . Both factors appear also to bind specifically to ISRE sequences(34, 35) .

We performed a functional analysis of the 5`-flanking region of IL-6 gene using transient transfection of CAT reporter gene linked to IL-6 promoter, in order to clarify the molecular mechanism involved in the synergistic induction by IFN- and TNF-alpha of the IL-6 gene in human monocytes. The monocytic THP-1 cell model appears to be particularly suitable for molecular dissection of IFN-/TNF-alpha-mediated synergistic induction of IL-6 gene expression, because in these cells, the IL-6 gene is not constitutively expressed(22) .

Analysis of IL-6 promoter constructs, electrophoresis mobility shift assay (EMSA), and immunoprecipitation analysis have shown that the synergistic induction of IL-6 gene by IFN- and TNF-alpha in human monocytic cells involved cooperation between IRF-1 and NFkappaB binding elements, as well as the removal of the negative effect of the retinoblastoma control element (RCE) present in the IL-6 promoter (IL-6-RCE). This IL-6-RCE contained, among other components, a core 5`-CCGCC-3` sequence homologous with the consensus binding motif, which is the target of the Sp1 factor. Sp1 is a constitutively expressed transcription factor present in a wide range of cell types and binds a GC-rich consensus sequence present in many cellular and viral promoters. Sp1 contains three zinc fingers that mediate DNA binding and four domains that mediate transcriptional activation(36) . Upon binding to the DNA containing the GC box in the cell nucleus, Sp1 becomes phosphorylated on multiple sites by double-stranded DNA-dependent kinase(37) . It has been shown that specific interaction between DNA-binding domains of the p65 subunit-NFkappaB and Sp1 bound the DNA modulates transcription of human immunodeficiency virus type 1 in response to cellular activation(38) .

Our results show that the contribution of IFN- to the triggering of IL-6 gene expression in human monocytes involves a change in the amount and phosphorylated state of Sp1, together with the induction and activation of IRF-1. These factors cooperate synergistically with homodimer p65-NFkappaB, which is activated by TNF-alpha.


MATERIALS AND METHODS

Cell Culture

THP-1 cells (strain TB202; American Type Culture Collection, Rockville, MD) were grown (7% CO(2)) in RPMI 1640 (Life Technologies, Inc.) supplemented with 10% heat-inactivated FCS shown to be endotoxin-free (<0.1 IU/ml; Myoclone, Life Technologies, Inc.).

Reagents

rHuIFN- (specific activity, 2 times 10^7 units/mg protein) was a gift from Roussel-Uclaf (Romainville, France); rHuIFN-alpha2 was provided by Shering (Kenilworth, NJ); rHuTNF-alpha (specific activity 6 times 10^7 units/mg protein) was produced by Genentech and provided by Boehringer-Ingelheim (Dr. G. R. Adolf, Vienna, Austria); LPS (Escherichia coli, serotype 0111:B4) was purchased from Sigma. Rabbit affinity-purified polyclonal antibodies against human Rb, Sp1, IRF-1, IRF-2, and NFkappaB family proteins were from Santa Cruz Biotechnology, Inc. (Tebu, France). Monoclonal anti-phosphoserine was from Sigma. Purified Sp1 protein was from Promega. Enhanced chemiluminescence (ECL) Western blotting kit reagent and Rabbit reticulocyte lysate system were from Amersham (Les Ulis, France).

IL-6-CAT Construct and the 5`-Deletion Mutants

A 1.2-kilobase pair BamHI-XhoI fragment which contained the IL-6 5`-flanking region of promoter (18) was deleted by using the Exo-mung deletion kit (Stratagene), inserted into a pCAT(TM)-Basic plasmid (Promega) at the SalI blunt end and HindIII sites, resulting in the following plasmids: del(-181) (-181 to +14), del(-108) (-108 to +14), del(-73) (-13 to +14), and del(-36) (-36 to +14). A del(-224) (-224 to +14) plasmid was generated by deleting the BamHI-NheI fragment (-1160 to -224). All resultant plasmids were verified by sequencing.

Transient Transfections

2 times 10^7 THP-1 cells (logarithmic growth phase, washed three times with PBS) suspended in 200 µl of DMEM (Dulbecco's minimal essential medium, Life Technologies, Inc.) were mixed gently with 15 µg of indicated dried supercoiled IL-6 promoter-plasmid DNAs and 5 µg of pSVbeta-galactosidase control plasmid as an internal reference (Promega) (purified by two cycles of CsCl gradient) and were electroporated at 220 V, 960 microfarads, for 42 ms using a Gene Pulser wired to an electroporation chamber (Bio-Rad). Cells were maintained at room temperature for 10 min before dilution in 10 ml of prewarmed RPMI 1640 supplemented with 10% FCS. Cells were stimulated 1 h later with IFN- (400 units/ml) and/or TNF-alpha (400 units/ml), or with LPS (1 µg/ml) in fresh RPMI 1640/10% FCS. After stimulation of 36 h, cells were analyzed for CAT activity, essentially as described by Gorman et al.(39) . Each CAT reaction was performed with 20 µg protein extract and 2.3 nmol of ^14C-labeled chloramphenicol (54 mCi/mmol) for 2 h at 37 °C. beta-Galactosidase enzyme was measured in the same cell extracts as described previously (40) .

Nuclear Extracts and EMSA

To prepare nuclear extracts, 40 times 10^6 cells were washed twice in chilled PBS and then resuspended in 500 µl of lysis buffer containing 10 mM HEPES (pH 7.9), 50 mM NaCl, 1 mM EDTA, 5 mM MgCl(2), 10 mM sodium orthovanadate, 10 mM sodium molybdate, 0.2 mM phenylmethylsulfonyl fluoride, 10 µg/ml protease inhibitors (pepstatin, leupeptin, aprotinin), and 0.05% Nonidet P-40. After swelling for 20 min on ice, glycerol was added (final concentration 5%, v/v) and nuclei were pelleted by centrifugation at 600 rpm for 10 min, at 2 °C. After rapid washing with the same buffer (containing 140 mM NaCl instead of 50 mM), the nuclei were gently resuspended in 100 µl of storage buffer containing 10 mM HEPES (pH 7.9), 400 mM NaCl, 0.1 mM EDTA, 0.5 mM dithiothreitol, 5% glycerol, 0.5 mM phenylmethylsulfonyl fluoride, 10 mM sodium vanadate, 10 mM sodium molybdate, and 10 µg/ml protease inhibitors. After 60 min on ice with gentle (and occasional) mixing, particulate matter was eliminated by centrifugation at 100,000 times g for 10 min at 4 °C. Protein content in the supernatant was determinated using Bradford's method(81) .

For EMSA, nuclear protein (10 µg) was incubated with radiolabeled probe (20,000 cpm) in buffer containing 50 mM NaCl, 10 mM HEPES (pH 7.9), 5 mM Tris-HCl (pH 7.9), 1 mM dithiothreitol, 15 mM EDTA, 10% glycerol, 500 µg/ml BSA-FV, and 800 µg/ml denaturated salmon sperm DNA (in a final volume of 12.5 µl) (without EDTA in the case of SP1 oligonucleotide probe). After a 30-min incubation on ice, the nucleoprotein complexes were resolved by a nondenaturing electrophoresis in a 5% polyacrylamide gel for 3 h at 20 mA in 1 times TGE buffer (50 mM Tris-HCl (pH 8.8), 180 mM glycine, and 2.5 mM EDTA), in refrigerated condition. The gel was dried and exposed overnight to a PhosphorImager screen (Molecular Dynamics, Sunnyvale, CA). For competition experiments, a 100-fold molar excess of the unlabeled oligonucleotides was added 15 min before incubation of nuclear extracts with the end-labeled oligonucleotides, while antisera were mixed directly with nuclear extracts and binding buffer (without salmon sperm DNA) 1 h before adding salmon sperm DNA and radiolabeled probe.

Immunoprecipitation and Immunoblot Analysis

Nuclear protein samples (150 µg) were precleared with rabbit IgG nonimmune antisera and protein A-Sepharose (Pharmacia) 2 h at 4 °C. After centrifugation (5 min, 4 °C), the supernatants were incubated with specific antibodies (1:500 dilution) overnight at 4 °C, and then 8 mg of protein G-Sepharose (Pharmacia) was added and gently rocked for 4 h at 4 °C. Protein A- and protein G-Sepharose were swollen in 50 mM Tris-HCl (pH 8.8), 500 mM KCl, 1% Triton X-100, 0.5 mM phenylmethylsulfonyl fluoride, 10 µg/ml protease inhibitors, 10 mM sodium molybdate, 10 mM sodium orthovanadate. The protein G-Sepharose immunocomplexes were successively washed three times with 100 mM Tris-HCl (pH 8.8), 500 mM KCl, 0.5% Triton X-100, once with 10 mM Tris-HCl (pH 7.6), 150 mM NaCl, 1 mM EDTA, 1% Triton X-100, 1% sodium deoxycholate, 0.1% SDS, 10% glycerol, and once with 10 mM Tris-HCl (pH 8.8). All washes were performed with buffers containing the anti-proteases and anti-phosphatases mixture. The proteins were eluted in 50 µl of 3% SDS, 30% glycerol, 150 mM KCl, 10 mM Tris-HCl (pH 6.7), 200 mM beta-mercapto ethanol (10 min at 95 °C), and specific immunoprotein complexes were separated by SDS-polyacrylamide gel electrophoresis, transferred to a nitrocellulose membrane (0.45 µM, Schleicher & Schuell) in refrigerated conditions (200 mA, 5 h). BSA-saturated membranes were incubated first with a specific antibody (overnight at 4 °C, 1:500 dilution, in PBS 5% BSA-FV, 0.1% Tween 20), washed with PBS, 0.1% Tween 20, and then incubated with I-protein A (Amersham, 500,000 cpm/ml of PBS containing 2% BSA-FV, 0.1% Tween 20) for 1 h at 20 °C. After extensive washing, membranes were exposed to PhosphorImager (Molecular Dynamics).

Shift-Western Blotting

Protein-DNA complexes were analyzed by EMSA, as described above. After polyacrylamide gel electrophoresis, Western blots were done by semidry blotting using the Multiphor II NovaBlot electrophoretic transfer unit (Pharmacia) as described by Demczuk et al.(41) . The first filter below the gel was nitrocellulose (BA85, 0.45 µm, Schleicher & Schuell) followed by a second anion-exchange filter DEAE membrane (Shleicher & Schuell). Radiolabeled components were detected by autoradiography on DEAE membrane. For protein detection, BA85 membrane was first blocked as described above for immunoblot analysis; primary antibodies were applied at a dilution of 1:1000, and ECL detection was performed according to the manufacturer's procedures (Amersham).

Nucleotide Sequences of Oligonucleotides Used in This Study

Purified synthetic oligonucleotides were provided by Eurogentec (Seraing, Belgium), and covered IL-6 promoter fragments between -73 and -54 (A; 5`-ctagaTGGGTTTTCCCATGAGTTCTt-3`), between -126 and -101 (B; 5`-ctagaGCCCCACCCGCTCTGGCCCCACCCTCt-3`), between -173 and -145 (C; 5`-ctagaATGCTAAAGGACGTAACATTGCACAATCTt-3`), between -207 and -184 (D; 5`-ctagaCTAAGCTGAACTTTTCCCCCTAGTt-3`), between -283 and -242 (E; 5`-ctagaTGAGTCACTAATAAAAGAAAAAAGAAAGTAAGGAAGAGTGGt-3`). Oligonucleotides with mutated sequences were also used: -283 mt15, 5`-ctagaTGGTTAGATAATAAAAGAAAAAAGAAAGTAAAGGAAGAGTGGt-3`, and -283 mt31, 5`-ctagaTGAGTCACTAATAAAAGAAAAAAGAAAGTCGCATAAGAGTGGt-3`. For competition experiments, we used synthetic oligonucleotides covering: (i) the NFkappaB binding site from the human immunoglobulin kappa light chain enhancer (42) 5`-ctagaCAGAGGGGATTTCCGAGAGGTt-3`, (ii) the IFN-alpha-stimulated response element (ISRE) of 2`,5`-oligo(A) synthetase (43) 5`-ctagaGATCCATGCCTCGGGAAAGGGAAACCGAAACTGAAGCCt-3`, (iii) the C3-IRF (44) 5`-ctagaAAGGGAAAGGGAAAGGGAAAGGGt-3`, (iv) the AP-1 consensus motif 5`-ctagaTGAGTCACTGAGTCACTGAGTCACt-3`, and (v) the SP1 consensus motif 5`-ctagaGATGGGCGGAGTTAGGGGCGGGACTATCt-3`(45) . The lowercase letters represent the bases included for creating restriction sites. The underlined letters indicate the mutated bases. After annealing, the synthetic double-stranded oligonucleotides were end-labeled using the Klenow-DNA polymerase and [alpha-P]dCTP (DuPont NEN) and were purified on Elutip(TM) columns (Schleicher & Schuell).

RNA Extraction and Northern Blot Analysis

Total cellular RNA was prepared by denaturation in guanidinium thiocyanate, followed by pelleting through a cesium chloride cushion(40) . For Northern blot analysis, 15 µg of total RNAs were loaded on a 1% agarose gel in MOPS buffer, containing 0,7% formaldehyde and transferred onto nylon Hybond N membrane (Amersham). Probe hybridizations (10^6 cpm/ml) were carried out overnight at 65 °C in a Rapid Hybridization Buffer (Amersham).

cDNA Probes

The cDNA probe for human IRF-1 was a 0.9-kilobase KpnI fragment excised from pUCIRF-1 vector. The human IRF-2 cDNA was a 1.2-kilobase XbaI fragment excised from pHIRF4S-51 vector. These cDNAs were a generous gift from Dr. T. Taniguchi (Osaka, Japan). The cDNA probes were labeled using the Redi-prime random primer labeling kit (Amersham), using [alpha-P]dCTP (DuPont NEN).

DNA Extraction

Plasmid DNA were prepared with the Qiagen plasmid kit (Qiagen, Coger, France), followed by two cycles of purification of closed circular DNA by equilibrium centrifugation in CsCl-ethidium bromide gradients(40) .


RESULTS

Functional Analysis of 5` Cis-regulatory Elements of the Human IL-6 Gene

Functional analysis of the 5`-flanking region of the human IL-6 gene was carried out using the -1200 to +14 fragment as well as a series of 5`-deletion mutants of IL-6 promoter, linked to a reporter pCAT-basic plasmid, which lacks both enhancer and promoter sequences (Fig. 1A). These plasmids were used to transfect THP-1 cells by electroporation, and 1 h later, the cells were stimulated by either IFN- and/or TNF-alpha, or by LPS, and tested for CAT activity after 36 h. When THP-1 cells were transfected with the construct containing 1200 base pairs of the IL-6 5`-flanking region, they exhibited a 5-fold increase in CAT activity in response to combined treatment with IFN- + TNF-alpha, and a 2.5-fold increase after IFN- treatment, but displayed no significant response to TNF-alpha alone. As expected, LPS induced a 7-fold increase in CAT activity (Fig. 1B), in agreement with the observations reported by other groups for other cell systems(3, 4, 17, 18, 19, 20) . Deletions of the regions between -1200 and -224 and between -1200 and -181 resulted in constructs whose respective CAT activities rose 4-fold and 2.5-fold in response to IFN- + TNF-alpha treatment, and 5-fold and 4-fold in response to LPS. Removal of the region spanning nucleotides -1200 to -224 abolished the sensitivity to IFN-. Deletion of the IL-6 promoter fragment up to nucleotide -108 resulted in a loss of the synergistic increase in CAT activity in response to IFN- + TNF-alpha stimulation, whereas 2-fold CAT activity was still observed after LPS.


Figure 1: Functional analysis of the 5`-cis-regulatory elements of the IL-6 gene: relative CAT activity. A, schematic extended map of the IL-6 promoter, with the locations of DNA motifs known to be implicated in IL-6 gene induction by various inducers, and deletion mutants of the human IL-6 promoter fused to the promoterless CAT gene. B, to assess basal promoter activity and its responsiveness to IFN- and/or TNF-alpha, and to LPS, THP-1 cells were tranfected as described under ``Materials and Methods.'' CAT activity was determined after 36 h. The IL-6 promoter response (-fold induction) is the ratio of CAT activity in stimulated cells to that in unstimulated cells, which is defined as 1.0. Values are means of eight independent experiments with standard deviation less than 10%.



Although successive deletions at the 5` end of the IL-6 promoter fragment resulted in a progressive reduction of the inducibility of CAT activity by LPS, the construct containing the region from -73 to +14 retained its sensitivity to LPS and continued to display a 3-fold increase in CAT activity. It was interesting to observe that this fragment became inducible by TNF-alpha and exhibited a 2-fold increase in CAT activity. However, no synergistic effect was induced by IFN- + TNF-alpha. Removal of the region from -1200 to -36 resulted in the complete loss of inducibility by IFN- and/or TNF-alpha, and by LPS (Fig. 1B).

The results of the deletion analysis described above suggested the presence of at least three regions differentially involved in IL-6 gene regulation by IFN- and/or TNF-alpha, and by LPS. The first region is a distal fragment between -1200 and -224 that positively regulates the response to IFN- alone. Although deletion of this fragment does not eliminate the synergistic IFN- + TNF-alpha response, a slide reduction in the magnitude of the induction of CAT activity is observed. Computer-based observation showed that this fragment contains an AP-1 site between -283 and -277, and a copy of the IFN enhancer core sequence 5`-AAAGGA-3` (-253/-248)(13) . The second region is a repressor element, i.e. the sequence between -181 and -73, which would negatively affect the synergistic response to IFN- and TNF-alpha without affecting sensitivity to LPS. This IL-6 DNA sequence contains, from -126 to -101, a direct repeat which is strikingly similar to the c-fos basal transcription element, with 21/26 nucleotides matching the RB-repressible RCE (the RB control element) identified in the c-fos gene(17, 46) . In this connection, Santhanam et al.(17) showed in functional assays that the overexpression of wild type RB in Hela cells strongly repressed the activity of IL-6 promoter constructs. In addition to these two elements, a third region located between -73 and -36, probably corresponding to the minimal element necessary for the LPS response, also allowed TNF-alpha sensitivity. Within this fragment were a putative AP-1 motif (-61 to -55) and the sequence 5`-GGGATTTTCC-3` (-72 to -63), which is highly homologous to the immunoglobulin kappa light-chain enhancer sequence 5`-GGGGACTTTCC-3`(42) .

Activation of Nuclear Protein(s) Binding to the IL-6 Promoter DNA Fragments after Stimulation of THP-1 Cells

To determine whether IFN- and/or TNF-alpha induced the binding of factors that specifically recognize DNA sequences in the IL-6 promoter, we prepared double-stranded synthetic oligonucleotides corresponding to IL-6 promoter DNA motif targets of specific transacting factors reported to be involved in the IL-6 gene induction in other cell types(3, 12, 13, 14, 15, 16) .

Nuclear protein extracts, prepare d from both untreated cells and cells stimulated for 1 h with either IFN- and/or TNF-alpha or with LPS, were submitted to EMSA with several radiolabeled double-stranded synthetic oligonucleotides. This experiment was an initial experiment, which was designed to screen the early induction of specific protein-DNA complexes.

Fig. 2shows an EMSA using five different oligonucleotides corresponding to (i) NFkappaB-like and AP-1 binding motifs (A/-73), (ii) IL-6-RCE (RB control element) target motif (B/-126), (iii) the typical cAMP/phorbol ester-responsive motif, and the IL-1/TNF-alpha responsive elements (C/-173), (iv) the negative regulatory domain-like sequence (and two putative copies of GGAAA motifs considered to be responsible for IFN inducibility (D/-207), and (v) the consensus AP-1 motif and a copy of the IFN enhancer core sequence 5`-AAAGGA-3` (E/-283)(13) .


Figure 2: IFN- and/or TNF-alpha, and LPS induce binding of specific nuclear proteins to the 5`-flanking region of the human IL-6 gene. A representative EMSA analysis showed the specific binding to oligonucleotide probes corresponding to IL-6 promoter fragments: A, -73 to -54 (lanes 1-6); B, -126 to -101 (lanes 7-13); C, -173 to -145 (lanes 14-19); D, -207 to -184 (lanes 20-25); E, -283 to -242 (lanes 26-32). To determine the binding specificity, nuclear extracts from untreated THP-1 cells, or cells treated for 1 h with IFN- and/or TNF-alpha or with LPS, were compared by EMSA: lanes 1, 7, 14, 20, and 26, untreated nuclear extracts; lanes 2, 8, 15, 21, and 27, IFN--treated nuclear extracts; lanes 3, 9, 16, 22, and 28, TNF-alpha-treated nuclear extracts; lanes 4, 10, 17, 23, and 29, IFN- + TNF-alpha-treated nuclear extracts; lanes 5, 11, 18, 24, and 30, LPS-treated nuclear extracts. a* indicates competition with specific unlabeled double-stranded oligonucleotides (lanes 7, 12, 18, 25, and 31), and b* indicates competition with unlabeled unrelated double-stranded oligonucleotide (lanes 13 and 32).



Formation of protein-DNA complexes was apparent with the three regions A, B, and E described above, which were involved in the functional response of the 5`-flanking regions of the IL-6 gene (Fig. 2). Surprisingly, no specific complexes were observed with regions C and D, previously reported to be involved in IL-6 gene regulation by various inducers in other cells systems(3, 4, 12, 13, 14, 15, 16) .

Induction of NF-kappaB Binding Activity by TNF-alpha in THP-1 Cells without Concomitant IL-6 Production

We investigated the kinetics of NFkappaB activation in IFN-- and/or TNF-alpha-treated THP-1 cells, and LPS-treated cells. Cells were stimulated by the various inducers for 0.5, 1, or 2 h and nuclear extracts analyzed for binding to the NFkappaB motif, using the radiolabeled synthetic oligonucleotide A/-73 (Fig. 3). Activated complexes were detectable within 1 h after stimulation with TNF-alpha alone, as well as with LPS (Fig. 3A). The binding activity shown after combined treatment with IFN- and TNF-alpha was similar to that obtained after treatment with TNF-alpha alone. The abundance of the complexes induced by TNF-alpha alone or combined with IFN- and by LPS increased throughout 2 h of stimulation without complex mobility change (Fig. 3A). After LPS treatment, the amount of the complexes increased throughout 4 h of stimulation; in contrast, TNF-alpha either alone or combined with IFN-, led to a transient increase for 2 h and dramatically decreased thereafter (data not shown). The specificity of the protein-DNA complexes was confirmed by complete competition of the binding with unlabeled oligonucleotide A/-73 as well as with the immunoglobulin NFkappaB consensus motif, and the absence of competition with AP-1 or SP1 consensus oligomers (Fig. 3B). We did not observe any specific binding complexes in untreated cells or in cells stimulated with either IFN- or IFN-alpha.


Figure 3: Kinetics of induction of NFkappaB-binding protein in THP-1 cells. A, THP-1 cells were stimulated with IFN- and/or TNF-alpha, with IFN-alpha, or wi th LPS. Nuclear extracts were prepared after cell stimulation for 0.5, 1, or 2 h. EMSA was performed using radiolabeled oligonucleotide A/-73. B, specificity of protein-DNA complexes. EMSA was performed with nuclear extracts from untreated cells (Cont) or cells stimulated for 2 h with TNF-alpha or LPS. Competition studies were carried out with specific oligonucleotides A/-73 (-73) and consensus NFkappaB, or with unrelated oligonucleotides AP-1, B/-126 (-126), or Sp1. In addition, binding studies including antibodies were carried out with two purified rabbit antisera, specifically reactive with p50 or p65 NFkappaB subunits (Ab p50, p65). NI, nonimmune antiserum added for nonspecific reactions. C, nuclear extracts from THP-1 cells, either untreated (Cont) or treated with various inducers for 2 h, were submitted to immunoprecipitation using either specific antibodies against p50 or p65 NFkappaB subunits, or nonimmune serum. After Western blot analysis, specific proteins were revealed with the corresponding antibodies, as described under ``Materials and Methods.'' Arrows point to specific p65 (left) or p50 (right) NFkappaB subunits. The relative mass of protein molecular markers is shown in the middle (Rainbow(TM), Amersham).



Polyclonal rabbit antibodies against p50 and p65 subunits of NFkappaB were used to probe the nuclear IL-6-NFkappaB binding complexes for the presence of corresponding proteins (Fig. 3B). Addition of antisera against the p65-NFkappaB subunit supershifted the protein-DNA complexes induced by TNF-alpha but impaired the formation of the complexes induced by LPS. Addition of antisera against the NFkappaB subunit p50 did not modify the TNF-alpha-induced complexes, but those induced by LPS were partially supershifted. Antibodies against the p52 and c-Rel NFkappaB subunits did not interact with any of these protein-DNA complexes. Nevertheless, combined treatment with antibodies against p65 + p52 + c-Rel NFkappaB subunits appeared to result in the disappearance of the minor residual complex left in TNF-alpha-treated cell extracts (data not shown). Results similar to those shown for the TNF-alpha-induced complexes were obtained using nuclear extracts of cells stimulated by IFN- + TNF-alpha. These results suggest that p65 is contained in the complexes, whatever the inducers used, whereas p50 only seems to be a constituent of the protein-DNA complexes induced by LPS.

To further investigate the subunit composition of the nuclear IL-6-NFkappaB binding complexes, nuclear extracts were immunoprecipitated with specific antibodies, and analyzed by Western blot (Fig. 3C). In agreement with the results shown in Fig. 3B, p65 subunit-NFkappaB was found afte r stimulation with TNF-alpha alone, with IFN- + TNF-alpha and LPS, whereas antibody against p50 only revealed a major protein of 50 kDa after LPS stimulation (Fig. 3C).

We previously showed that in THP-1 cells, stimulation by combined treatment with IFN- and TNF-alpha was required for endogenous IL-6 gene expression and protein secretion, and that TNF-alpha treatment alone was ineffective(22) . Here, however, TNF-alpha was effective in activating nuclear protein binding to the NFkappaB-like element and in driving CAT expression after transfection with the del(-73) construct containing the NFkappaB-like sequence. These observations suggested the presence of a repressive element(s) that might negatively affect TNF-alpha-mediated transcription of the endogenous IL-6 gene.

Involvement of RCE (Retinoblastoma Control Element) in IL-6 Gene Repression in THP-1 Cells: Role of SP1 Protein

It was reported that Rb protein but not its mutants, repress IL-6 promoter transcriptional activity in NIH 3T3 cells(17) . This repression was mediated through a cis-acting element, first described in the c-fos promoter(46) . The IL-6 promoter contains a G+C-rich sequence between -126 and -104 that includes two CCACC motifs (-123 to -118 and -109 to -103) previously identified as the RB response element (RCE), and one CCGCC motif similar to the Sp1-binding site (-119 to -115)(12, 13) .

The results shown in Fig. 1suggest that a cis-DNA element, which is located between -181 and -73 and contains, among others, the RCE motifs, might be involved in repression of IL-6 gene expression in THP-1 cells. These observations prompted us to investigate the interactions between proteins and the IL-6-RCE sequence in nuclear extracts of THP-1 cells stimulated with various inducers. For this investigation, we used an oligonucleotide spanning both sites (B/-126). EMSA revealed the presence of a major constitutive complex in untreated cells (Fig. 4A, left section). No major modification was observed after this stimulation. Complex formation was specific, since it competed with the non-radiolabeled specific oligonucleotide but not with the unrelated oligonucleotide AP-1 (Fig. 4B). Note that protein-DNA interactions appeared to involve the Sp1 elements, since binding displayed complete competition with a Sp1 consensus motif (Fig. 4B).


Figure 4: Specificity of protein binding to RB control elements. A, EMSA was performed with nuclear extracts of THP-1 cells, either untreated or stimulated for 0.5 h with IFN- and/or TNF-alpha, LPS, or IFN-alpha, using radiolabeled double-stranded oligonucleotide B/-126 (left section), or radiolabeled consensus Sp1 oligonucleotide (right section). B, nuclear extracts of cells left untreated for 0.5 h (Cont) were submitted to EMSA using the B/-126 radiolabeled probe to reveal specific competition between RCE-binding proteins and either unlabeled double-stranded oligonucleotide B/-126 or Sp1 consensus oligonucleotide. AP-1 unlabeled oligonucleotide was used as unrelated competitor. Nuclear extracts of untreated cells (Cont) or IFN--treated cells were preincubated with antibodies (Ab) against Rb protein (Rb) or against Sp1 protein (Sp1), and radiolabeled probe B/-126 was then added. Recombinant Sp1 protein (1.0 footprinting units) was mixed with nuclear extract of untreated cells (Cont) or cells treated with IFN-, and radiolabeled B/-126 probe was then added (right section). C, specifity of the EMSA complexes revealed with radiolabeled probe Sp1. Before the addition of radiolabeled Sp1 oligonucleotide, nuclear extracts of untreated cells or cells treated with IFN-, TNF-alpha, or IFN- + TNF-alpha were mixed either with unlabeled oligonucleotide (-126, Sp1), or with antibodies (Ab) against Sp1 protein or Rb protein; NI corresponded to nonimmune rabbit antiserum. Sp1 protein (1.0 footprinting unit) was added to the same nuclear extracts. D, immunoprecipitation of nuclear extracts of untreated THP-1 cells (Cont) or cells stimulated with IFN- alone or IFN- + TNF-alpha, using antibodies against Sp1 protein, followed by Western blot analysis. Upper part shows blot hybridization with Sp1 antibodies. Lower part, the same blot was dehybridized and reprobed with antibodies against phosphoserine protein. Left arrows point to the specific Sp1 protein. Right arrows (mass in kDa) point to the relative mass of protein molecular markers.



Antibodies against purified Sp1 protein partially supershifted the B/-126 complex, whereas antibodies against Rb protein had no effect on complex formation (Fig. 4B). Furthermore, addition of purified Sp1 protein to the nuclear extracts led to a higher site occupancy without changing mobility (Fig. 4B, right section).

Taken together, these results suggest that Sp1 is part of the protein-DNA complex formed with B/-126 oligonucleotide. This oligonucleotide, which encompasses the RCE-IL-6 promoter element, includes the core sequence 5`-CCGCC-3` (-119 to -115), which covers part of the RCE motif (-123 to -118); this motif appears to be homologous with the 5`-CCGCCC-3` core sequence, reported to be the consensus binding motif involved in the interaction with the Sp1 factor. Furthermore, when we used an Sp1 consensus oligonucleotide as the radiolabeled DNA probe in EMSA experiments, a major constitutive complex was revealed (Fig. 4A, right section) with a mobility similar to that obtained with the B/-126 probe (Fig. 4A, left section). The amount of the protein-Sp1 oligonucleotide complex rose slightly after stimulation by IFN-, TNF-alpha, LPS, or IFN-alpha, and rose more markedly after combined stimulation with IFN- + TNF-alpha. Complex formation was impaired by competition with the specific unlabeled Sp1 oligonucleotide, and partial competition was observed with the B/-126 oligonucleotide (Fig. 4C). As expected, antibodies against the Sp1 protein led to a supershift of the protein-DNA complex, whereas no effect was observed with pRb antibodies. In the same way, as for the B/-126 probe complex, addition of Sp1 protein greatly increased the amount of protein-DNA complex revealed with the Sp1 oligonucleotide probe.

To demonstrate the presence of Sp1 protein in the B/-126 DNA protein complex, we used shift-Western blot analysis, with either the B/-126 probe or the Sp1 consensus probe. When a complex was formed with the B/-126 probe (Fig. 5, A1), we could not reveal the presence of Rb protein (A2), whereas the antibodies against Sp1 protein recognized a specific protein whose abundance increased slightly after IFN- + TNF-alpha treatment (A3). The antibodies against Rb protein identified a fain t lower band, probably corresponding to free Rb protein (Fig. 5, A2).


Figure 5: Sp1 protein is part of IL-6-RCE-protein complex. EMSA was performed using either the radiolabeled B/-126 oligonucleotide (A) or the radiolabeled Sp1 consensus oligonucleotide (B). Shift-Western blot analysis was then performed as described under ``Materials and Methods.'' Radiolabeled DNA was visualized on DEAE membrane (A1 and B1) whereas either Rb protein (A2 and B2) or Sp1 protein (A3 and B3) was revealed on nitrocellulose by Western blot analysis using the respective specific antibodies against Rb protein and Sp1 protein.



As expected, in a similar experiment using a radiolabeled Sp1 probe (Fig. 5B), antibodies against Sp1 protein revealed a specific protein contained in the protein-DNA complex (B3); the amount of Sp1 protein correlated with the amount of DNA probe bound to this complex (B1), which increased after IFN- + TNF-alpha treatment (B3). A faint lower band was also seen, probably corresponding to free Sp1 protein. With pRb antibodies, no protein was revealed in the protein-DNA complex, and as in the experiment using the B/-126 probe, a lower band was detected, corresponding to free Rb protein (Fig. 5, B2).

Immunoprecipitation of crude nuclear extracts of THP-1 cells stimulated with IFN- alone or combined to TNF-alpha, using antibodies against Sp1 protein, dramatically raised the level of the 95-kDa native Sp1 protein as shown by Western blot analysis (Fig. 4D, upper section). To demonstrate that the effect of IFN- or IFN- + TNF-alpha correlated with the activation of Sp1 protein, the same immuno-Western blot was hybridized with a monoclonal anti-phosphoserine antibody. Fig. 4D (lower section) shows an increase in phosphorylated Sp1 protein, previously reported to be the active form of this nuclear factor(36) . These results correlate well with the increase in binding activity shown by EMSA performed with the Sp1 probe after THP-1 cell treatment with IFN- + TNF-alpha (Fig. 4A, right s ection).

Taken together, these results suggest the involvement of the Sp1 protein in the protein-DNA interaction of the RCE present in the IL-6 promoter. Although we cannot exclude the possibility that other factors interact with the RCE-IL-6 promoter, shift-Western blot and antibody-supershift experiments nevertheless suggest that Sp1 is part of the activity that interacts with this region.

Regulation of IRF-1 and IRF-2 in the Synergistic Induction of IL-6 Gene Expression by IFN- + TNF-alpha

Functional analysis (Fig. 1) showed that a distal element between -1200 and -224 regulates positively the response to IFN- alone, or combined with TNF-alpha. EMSA using probe E/-283, and encompassing a copy of the IFN enhancer core sequence, revealed the formation of 2 protein-DNA complexes, one of which was specifically induced by IFN- treatment (Fig. 2). We investigated the kinetics of complex activation in THP-1 cells treated with IFN- and/or TNF-alpha, LPS, and IFN-. The same nuclear extracts as those already used for the NFkappaB experiments were analyzed for binding activity to the IFN-enhancer motif, using probe E/-283 (Fig. 6A). In untreated cells, EMSA revealed the presence of a constitutive DNA-protein complex, C1 whose amount increased in a time-dependent manner after stimulation by IFN- and IFN- + TNF-alpha. The amount of this C1 compl ex was not modified by TNF-alpha, LPS, or IFN-alpha. Note that, IFN- alone induced a second protein-DNA complex (C2), which was not observed after TNF-alpha or LPS stimulation. EMSA carried out with nuclear extracts of cells treated with IFN-alpha for 2 h revealed a faint C2 complex.


Figure 6: Induction and specificity of IFN- regulated IRF-1/IRF-2 complexes. Radiolabeled double-stranded oligonucleotide E/-283 was used for EMSA. A, binding reactions were tested with nuclear extracts prepared from untreated THP-1 cells or cells treated with various inducers for 0.5, 1, or 2 h. Arrows indicate C1- and C2-specific protein-DNA complexes. B, nuclear extracts from THP-1 cells treated for 2 h with IFN- + TNF-alpha were used to determine the specificity of the two complexes by means of the following unlabeled double-stranded oligonucleotides: E/-283 without mutation (-283), or with mutation (mt) in the AP-1 motif (mt 15) or in the IFN enhancer core sequence (mt 31), ISRE, and C3. Oligonucleotides AP-1, B/-126(-126) and Sp1 were used as nonspecific competitors. C, before addition of radiolabeled probe E/-283, nuclear extracts from THP-1 cells treated with IFN- + TNF-alpha for 2 h were preincubated with antibodies against IRF-2, IRF-1, or nonimmune antiserum (NI).



To define the sequence specificity of the C1 and C2 complexes, competition experiments were performed with synthetic oligonucleotides representing several mutations of the -283 to -242 region either in the putative interferon enhancer core sequence 5`-AAAGG-3` (-283/mt31) or in the AP1 motif (-283/mt15), and also with the ISRE of the 2`,5`-oligo(A) synthetase gene promoter, known to be implicated in IFN responses(43) , and with the C3 oligonucleotide defined by its IRF-1-binding activity(44) .

Oligonucleotide E/-283 and the mutant -283/mt15 competed for the formation of both complexes (Fig. 6B, mt 15), whereas the mutant -283/mt31 lost this capacity (Fig. 6B, mt 31), indicating that the IFN enhancer core sequence 5`-AAAGG-3` was involved in the DNA-protein interaction. Complete competition for the C1 and C2 complexes was observed with the ISRE and C3 oligonucleotides. A trimer AP-1 motif was not able to compete for either complex, in agreement with the behavior of mutant -283/mt15. No competition was observed neither with the Sp1 nor with B/-126 oligonucleotides (Fig. 6B).

To investigate the possible relationship between the C1 and C2 complexes and ISGF3(25, 26, 27, 47) , nuclear extracts of THP-1 cells treated for 2 h with IFN-alpha were tested for their binding activity, using the E/-283, ISRE, or C3 oligonucleotides as DNA radiolabeled probes (Fig. 7). The pattern of the protein-DNA complexes was very similar with the E/-283 and C3 oligonucleotide probes, suggesting that they bind the IRF-1-related factor. For ISRE-DNA-protein binding, only IFN-alpha treatment resulted in a double upper-induced binding activity (Fig. 7); several constitutive complexes showed no quantitative or qualitative changes, whatever the inducers used. These results suggest that C1 and C2 complexes did not involve ISGF3, but rather IRF-1/IRF-2, unlike the IFN-alpha-induced complexes revealed with the ISRE probe.


Figure 7: E/-283, C3-radiolabeled oligonucleotides, and ISRE-radiolabeled oligonucleotide gave different patterns of the protein-DNA complexes. Nuclear extracts of THP-1 cells treated for 2 h with IFN-, TNF-alpha, IFN- + TNF-alpha, LPS, or IFN-alpha were tested for their binding activity, using oligonucleotides radiolabeled with E/-283 (left section), C3 (middle section), or ISRE (right section). Double arrows indicate specific protein-DNA complexes.



As shown in Fig. 6C, the amount of constitutive DNA-binding C1 complex was markedly reduced by the IRF-2 antibodies, while the inducible complex C2 was supershifted by the IRF-1 antibodies. The IRF-1 antibodies also abolished the time-dependent increase in the C1 complex, which remained at its constitutive level. These results demonstrate that IRF-2 is involved in the formation of the constitutive C1 complex, and that IRF-1 is involved both in the formation of the inducible C2 complex and in the increase in the amount of C1 complex.

To establish whether this typical IRF recognition sequence is sufficient for IFN- activation and for the synergistic action of IFN- with TNF-alpha, we constructed mutated IL-6 promoter CAT expression plasmids. For this purpose, we linked oligonucleotide E/-283, or oligonucleotide -283/mt31, which carried a mutation in the putative IFN enhancer core sequence AAAGGA (-253 to -248), to del(-224)-CAT and called the resulting constructs del(-224)/E and del(-224)/Emt31, respectively (Fig. 1A). These constructs were then transfected into THP-1 cells. As shown in Fig. 1B, the relative induction of CAT activity after THP-1 transfection with construct del(-224)/E demonstrated that the IFN enhancer core sequence is sufficient to confer responsiveness to IFN-, because the mutation of the AAAGGA motif (see del(-224)/Emt31) abolished IFN- sensitivity; the IFN- + TNF-alpha synergistic induction was preserved, although to a much smaller extent (2-fold induction). These results suggest that in addition to the IFN enhancer core sequence, surrounding sequences might contribute to the synergistic effect of IFN- with TNF-alpha.

Transfection of either of the constructs del( -224)/E or del(-224)/mt31 resulted in a similar LPS-induced increase in CAT activity (7- and 6-fold, respectively), showing that the IFN enhancer core sequence did not play an essential role in LPS induction (Fig. 1). However, LPS inducibility required the cooperation of other(s) factor(s), as demonstrated by the progressive reduction of CAT activity after the transfection of IL-6 promoter 5` end successive deletions.

These results showed that IFN- + TNF-alpha and LPS induced the IL-6 gene by different pathways.

Differential Regulation of IRF-1 and IRF-2 Expression by IFN- or LPS

Previous reports have shown that the IRF-1 and IRF-2 factors display antagonist activities, and that the up-regulation of the binding activity of one factor results in the down-regulation of the binding activity of the other(28, 29, 30, 31, 32) . Our demonstration that the binding activities of IRF-1 and IRF-2 correlated with the synergistic induction of IL-6 promoter by IFN- + TNF-alpha (Fig. 6) prompted us to compare the regulation of IRF-1/IRF-2 by IFN-, TNF-alpha, or IFN- + TNF-alpha with their regulation by IFN-alpha.

For this purpose immuno-Western blot analysis of nuclear extracts of THP-1 cells after 2 h of stimulation was performed using antibodies against IRF-1 or IRF-2. A polypeptide of 42 kDa was revealed by the IRF-1 antibodies, but only after stimulation by IFN- or IFN- + TNF-alpha (Fig. 8A, right section). The IRF-2 antibodies detected a constitutive IRF-2 protein whose abundance was not modified after cell treatment with IFN- or TNF-alpha either alone or combined for 2 h. In contrast, treatment with LPS or IFN-alpha reduced the amount of IRF-2 protein (Fig. 8A, left section). Since formation of the constitutive C1 complex involved IRF-2 protein binding (see Fig. 6C), we attempted to establish whether a transient modulation of this protein occurred soon after stimulation. As shown in Fig. 8A (left section), treatment with IFN- + TNF-alpha, LPS, or IFN-alpha reduced the level of IRF-2 protein in nuclear extracts of cells stimulated for 30 min. The effect of IFN-+TNF-alpha was transient, because the reduction in the amount of IRF-2 protein was not seen in nuclear extracts of cells that had been stimulated for 2 h. In contrast, the inhibition by IFN-alpha or LPS of the IRF-2 protein level lasted throughout the 2 h of stimulation.


Figure 8: Modulation of IRF-1 or IRF-2 proteins. A, nuclear extracts of untreated THP-1 cells (CONT) or cells treated with various inducers for 30 min (upper section) or for 2 h (lower section) were submitted to immunoprecipitation using specific antibodies against IRF-1 or IRF-2, followed by Western blot analysis. IRF-2 protein was analyzed after treatment of THP-1 cells for 30 min or 2 h by various inducers, whereas IRF-1 protein was analyzed after cell stimulation for 2 h. Middle arrows indicate the relative mass of protein molecular weight markers. Left or right external arrows indicate specific IRF-2 or IRF-1 proteins. B, in vitro translation: total RNAs were extracted from cells left untreated for 2 h (Cont) or stimulated for 2 h, and were translated in vitro at a concentration of 480 µg total RNA/ml, using reticulocyte lysate and [S]methionine under defined optimal conditions (97 mM KCl and 1.8 mM Mg(CH(3)COO)(2)). After incubation of 1 h at 32 °C, volume aliquots corresponding to 5 times 10^6 cpm of labeled polypeptides were submitted to immunoprecipitation followed by Western blot analysis, as described under ``Materials and Methods.''



Since the amount of IRF-2 protein diminished after cell stimulation by IFN- + TNF-alpha, LPS, or IFN-alpha, whereas IRF-1 protein was only induced by IFN-, we explored this effect to see if it was related to an increase in IRF-1 and (or) a decrease in IRF-2 gene expressions. For this purpose, total RNAs were extracted after 0.5, 1, or 2 h from cells stimulated with various inducers and then analyzed by Northern blot. As shown in Fig. 9, IFN- already induced IRF-1 mRNA after 30 min, in an amount which increased for up to 2 h of cell stimulation. No synergistic effect was observed after combined treatment with IFN- and TNF-alpha. Stimulation by IFN-alpha also triggered IRF-1 gene expression, but with different kinetics of accumulation since IRF-1 mRNA was barely detected after 1 h of IFN-alpha stimulation but its amount increased thereafter. Two IRF-1 mRNAs of 2.1 and 3 kilobases were revealed, with a similar accumulation kinetic. Neither TNF-alpha nor LPS induced IRF-1 gene expression in THP-1 cells.


Figure 9: Kinetics of IRF-1 and IRF-2 gene expression in THP-1 cells. Total RNAs (15 µg) of THP-1 cells treated with the indicated inducers for 0.5, 1, or 2 h were analyzed by Northern blot hybridization with the IRF-1-radiolabeled probe. After dehybridization, the same membrane transfer was successively hybridized with IRF-2 and actin probes. Arrows indicate specific mRNA.



In contrast, IRF-2 mRNA was constitutively expressed (Fig. 9). No significant modification of the IRF-2 mRNA level was observed whatever the period of incubation and the inducers used. The reduction in the level of this protein after stimulations with various inducers, without concomitant decrease in the IRF-2 mRNA level, prompted us to make sure that IRF-2 mRNA was functionally active. Accordingly, total RNAs were extracted from cells left untreated from 2 h or stimulated for 2 h and translated in vitro, using reticulocyte lysate and [S]methionine. Identical number of counts/min (5 times 10^6 cpm) were analyzed by immuno-Western blot, using specific IRF-2 antibodies. Similar amounts of IRF-2 protein were detected whatever the inducers used (Fig. 8B).

These results indicate that the differential regulation of IRF-2 protein by IFN-, LPS, and IFN-alpha takes place at post-translational level.


DISCUSSION

We investigated the molecular basis for the IFN-/TNF-alpha-mediated synergistic induction of the human IL-6 gene in the THP-1 monocytic cell line by functional analysis of this gene's promoter. The results provided evidence that three regions inside this promoter are the targets of the IFN-/TNF-alpha action: (i) a region between -73 and -36, which constitutes the minimal element inducible by LPS or TNF-alpha; (ii) an element located between -181 and -73, which appears to regulate negatively the response to IFN- and TNF-alpha; and (iii) a distal element upstream of -224, which is the only one inducible by IFN- alone.

Each of the DNA elements corresponding to the three functional regions inducible by IFN- and/or TNF-alpha and by LPS led to the formation of specific DNA-protein complexes.

The IL-6 promoter DNA fragment between -73 and -36 was found to contain an NFkappaB-like element near a putative AP-1 binding motif. In THP-1 cells, TNF-alpha or LPS induced binding to this DNA motif, whereas IFN- neither induced NFkappaB binding activity nor amplified the effect of TNF-alpha when added together with it. The EMSA-DNA competition experiments with consensus immunoglobulin-kappaB oligonucleotide allowed us to conclude that the formation of the complexes induced by TNF-alpha and LPS is due to NFkappaB binding factors. EMSA including antibodies and immunoprecipitation with anti-p50 and anti-p65 NFkappaB subunit antibodies revealed only the nuclear accumulation of p50 and p65 after stimulation by LPS. The predominance of the p65 subunit was shown to be the major factor induced by TNF-alpha or IFN- + TNF-alpha. Various dimer combinations of induced factors have been reported to be stimulus-dependent and to display distinct DNA binding specificities by activating distinct sets ot target genes(23) . Thus, homodimer p65 was previously shown to be selectively activated in other systems by TNF-alpha(48, 49) .

In THP-1 cells, the induction of NFkappaB binding activity by TNF-alpha did not correlate with concomitant IL-6 production(22) , but required the addition of IFN-, unlike activation by LPS. This indicated that the mechanism involved in the induction of endogenous IL-6 gene in THP-1 cells is inducer-specific.

Although NFkappaB binding factors are certainly involved in IL-6 gene induction, the functional analysis of IL-6-CAT construct deletions reported here shows that significantly greater stimulation of the CAT reporter gene is obtained for constructs that contain the 5` distal sequence of IL-6 promoter (pr-1200). Successive deletions of the 5` end of the IL-6 promoter fragment (-1200 to -108) resulted in the gradual reduction of synergistic CAT activity by IFN- + TNF-alpha.

EMSA using the oligonucleotide E/-283, which contains a copy of IFN-enhancer-core sequence, showed that IFN-, but not TNF-alpha or LPS, induced specific binding activity. Similar results were obtained with C3 oligonucleotide, suggesting that an IRF-1-related factor was a component of the C1- and C2-specific protein-DNA complexes. EMSA experiments using antibodies against IRF-1 or IRF-2 allowed us to conclude that the formation of the constitutive C1 complex involved IRF-2 binding and that IRF-1 was involved, both in the binding activity of the inducible C2 complex and in the increased abundance of the C1 complex due to stimulation by IFN-.

In agreement with these findings, transfection of construct del(-224)/Emt31 into THP-1 cells confirmed that the IFN-enhancer-core sequence AAAGG, which is located between -253 and -248(13) , is sufficient to induce the response to IFN- alone.

The IRF-1 binding site identified in the IL-6 promoter was shown to be the central motif of the IFN-stimulated response element (ISRE) found in the promoter of IFN-alpha-stimulated genes such as the 2`,5`-oligo(A)-synthetase gene(43) . In EMSA using the E/-283 probe, the IRF-related complexes C1 and C2 were impaired by the ISRE oligonucleotide. However, after IFN-alpha treatment, no C1 or C2 binding activity was observed. When EMSA was performed with the ISRE oligonucleotide for purposes of comparison, it only revealed ISGF3-related complexes after IFN-alpha treatment, as expected (24, 25, 26, 27) .

Induction of IRF-1 protein-DNA binding by IFN- correlated with the induction of IRF-1 mRNA and with the concomitant IRF-1 protein synthesis. On the other hand, IRF-2 mRNA constitutive expression was not modified whatever the inducers, whereas the level of constitutive IRF-2 protein decreased transiently after IFN- + TNF-alpha treatment. LPS or IFN-alpha treatment led to the disappearance of the constitutive IRF-2 protein.

The different effects exerted on IRF-2 protein down-regulation by IFN- + TNF-alpha on the one hand and by LPS on the other might partly account for the difference between the magnitude of IL-6 induction by each of these inducers in monocytic THP-1 cells.

LPS was recently shown to induce or activate proteins that recognize the 3`-end instability sequence of an mRNA that prevents the latter's translation(50, 51, 52) . Such a mechanism might account for the down-regulation of IRF-2 protein in vivo, since here we were unable to show by Northern blot analysis that this inducer modulates either the expression of mRNA IRF-2 or its translation in vitro. Alternatively, the constitutive IRF-2 protein might be rapidly degraded after its activation by IFN- or LPS, as shown in other systems(53) , thus allowing the binding of another activator which in the case of IFN- would be IRF-1.

As LPS did not, under our experimental conditions, induce IRF-1, we might be justified in assuming that one or several other factors activated by LPS could act as a transcriptional factor, as suggested by our functional CAT analysis (Fig. 1B).

Our results suggest that IRF-1 may be a critical downstream signaling factor involved in IFN- signal transduction in monocytes/macrophages, particularly for genes whose maximal expression is triggered by combined treatment with IFN- + TNF-alpha(22, 54, 55, 56) .

The fact that TNF- alpha induced NFkappaB binding activity, which correlated with the inducibility of the del(-73)-CAT construct but failed to induce reporter constructs containing additional upstream sequences, suggests that a silencer of NFkappaB activity must be present in the IL-6 promoter. Functional analysis of deletion constructs indicated that this negative element might be located between -181 and -73. This region contains, among others, a retinoblastoma control element known to be involved in pRb-mediated repression of the c-fos promoter(46) . The presence, as reported by Santhanam et al., of a region analogous to the RCE in the IL-6 promoter between positions -126/-101, exhibiting similar patterns of c-fos and IL-6 promoters regulation, suggests that RCE may be involved in IL-6 gene repression in monocytic cells. Evidence that RCE has a repressor role was obtained, in NIH 3T3 cells, by deletion experiments and cotransfections of IL-6 promoter with pRB expressing vector (17) .

It is tempting to suggest that alteration(s) in the interaction between the putative suppressor factor(s) and RCE allowed us to obtain a synergistic effect of IFN- with TNF-alpha in THP-1 cells. Synergistic CAT induction was observed for del(-181) but not for del(-108). The del(-181)-CAT construct contains the intact IL-6-RCE motif, whereas a truncated RCE motif is present in the del(-108)-CAT construct.

EMSA experiments performed with oligonucleotide B/-126, which contains the IL-6-RCE motif, revealed one major constitutive specific RCE-protein complex in nuclear extracts of THP-1 cells. This complex was completely inhibited by consensus Sp1 oligonucleotide and was supershifted by Sp1 antibodies. In addition, recombinant Sp1 protein increased this site occupancy. Furthermore, we showed by shift-Western blot analysis that Sp1 protein is part of the IL-6-RCE-protein complex, whereas Rb protein, undetectable in this complex, was not.

Our observations are in agreement with the hypothesis proposed by Udvadia et al. that Rb regulates transcription partly by virtue of its ability to interact functionally with RB control proteins, including Sp1(45, 57, 58, 59, 60) .

EMSA performed with the Sp1 consensus probe showed that stimulation of THP-1 cells by IFN- + TNF-alpha enhanced the amount of the protein-DNA complex. This result correlates with a marked increase by IFN- in the amount of serine-phosphorylated Sp1 protein.

It has been shown that Sp1 is selectively phosphorylated upon binding to its cognate recognition elements on DNA, suggesting that phosphorylation represents an early event in the processes leading to transcriptional activation by Sp1. Phosphorylation of Sp1 is catalyzed by a double-stranded DNA-dependent kinase and requires binding to DNA containing the GC box(34, 61) .

It is tempting to postulate that the effect of IFN- was partly mediated by increased binding of Sp1 to its target sequence in the IL-6 promoter, with concomitant Sp1 factor activation by specific phosphorylation. This alteration might impair the negative effect mediated by the IL-6-RCE.

On the other hand, NFkappaB has been shown to synergize with a number of transcription factors, including Sp1(62, 63) . It has been reported that Sp1 specifically interacts with the N-terminal region of Rel A (p65); similarly, Rel A (p65) bound directly to the zinc finger region of Sp1 factor. This interaction is specific, because Rel A did not associate with several other transcription factors known to be zinc finger proteins(36, 37, 38) . Since the p65 homodimer induced by TNF-alpha in THP-1 cells is not, by itself, sufficient to induce IL-6 gene expression, we can postulate that functional interaction between p65 NFkappaB and the activated-Sp1 bound to the adjacent target Sp1 site contributed to the induction of the IL-6 gene.

Our observations allowed us to conclude that IL-6 gene expression in THP-1 cells by IFN- + TNF-alpha, or by LPS treatment is mediated through different signaling pathways.

LPS signaling was shown to involve interaction with CD14(64, 65) , which triggered the mitogen-activated protein kinase Ras-Raf1-dependent cascade, leading to IkappaB phosphorylation and subsequent translocation allowing accumulation of the p50/p65 NFkappaB heterodimer in the nucleus(23, 66, 67, 68) . Since this p50/p65 complex was also identified in our cell system, a similar pathway might be responsible for the IL-6 gene expression induced by LPS treatment in THP-1 cells.

In contrast, the synergistic effect of IFN- + TNF-alpha on IL-6 gene induction in THP-1 cells might involve three simultaneous processes. The first process is the activation of NFkappaB by TNF-alpha by a different pathway from that of activation by LPS, leading to the activation of the p65 homodimer. This possibility is supported by a recent report showing that, in murine macrophages, TNF-alpha activates the mitogen-activated protein kinase cascade in a mitogen-activated protein kinase kinase kinase-dependent but c-Raf-1-independent fashion(69) . The second process is the induction of IRF-1 by IFN- through a signaling pathway involving the activation of Jak1/Jak2 and Stat 1(70, 71, 72, 73, 74, 75) . The third process is a concomitant change by IFN-, in the state of phosphorylation and abundance of the constitutive Sp1 nuclear factor interacting with IL-6-RCE. The phosphoserine kinase implicated in the signaling pathway leading to phosphorylation of Sp1, presumably activated by IFN-, remains to be investigated. Transcriptional induction of the IL-6 gene might result from a coordinated effect exerted by factor Sp1 together with IRF-1 and p65 homodimer-NFkappaB.

The fact that regulation by IFN- of the IL-6 gene in human monocytes involved IRF-1 may be more generally related to the tumor suppressor/differentiation properties of IFN-(32, 76) . Deletion of a chromosomal segment that contains the IRF-1 gene, mapped in chromosome 5q31.1, is very often observed in human leukemia(77) . It is therefore possible that an alteration in the balance of IRF-1/IRF-2 may impair optimal physiological induction of IL-6 by IFN-/TNF-alpha in the monocytic cell compartment, leading to abnormal cell maturation and proliferation in certain hematological disorders and to neoplasia.

Alterations in IL-6 production such as overexpression in multiple myeloma and other type of cancers(2, 3, 4, 5, 6, 7, 8, 9, 78, 79) or inhibition in Fanconi's anemia (10, 80) may be suspected to play a role in pathological cell growth and to affect hematopoietic cell differentiation. In this regard, the fact that the triggering of IL-6 gene expression by IFN- in monocytic cells required the induction of IRF-1 and involved phosphorylated Sp1 protein may be of physiological relevance, and one of the important homeostatic properties of IFN- within the cytokine network.


FOOTNOTES

*
This work was supported by grants from the Institut National Scientifique et de la Recherche Médicale (INSERM) and the Association pour le Recherche contre le Cancer (ARC). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
To whom correspondence should be addressed: INSERM U365, ``Interferons et Cytokines,'' Institut Curie, Section de Recherches, 26, rue d'Ulm, 75231 Paris, France. Tel.: 33-1-4325-8267; Fax: 33-1-4407-0785.

(^1)
The abbreviations used are: IL-6, interleukin-6; TNF-alpha, tumor necrosis factor-alpha; EMSA, electrophoresis mobility shift assay; IRF-1, interferon-regulatory factor 1; RCE, retinoblastoma control element; FCS, fetal calf serum; PBS, phosphate-buffered saline; BSA, bovine serum albumin; IFN, interferon; MOPS, 4-morpholinepropanesulfonic acid; ISRE, IFN-alpha-stimulated response element; ISGF3, interferon-stimulated gene factor 3.


ACKNOWLEDGEMENTS

We thank Dr. T. Taniguchi (Osaka, Japan) for the generous gift of IRF-1 and IRF-2 cDNAs, Dr. G. R. Adolf (Boehringer-Ingelheim, Vienna, Austria) for the gift of human TNF-alpha, and Dr. Lando (Roussel-Uclaf, Romainville, France) for the gift of human IFN-. We are grateful to A. Birot for expert secretarial assistance and to C. Sylvestri for valuable technical assistance for plasmid-DNA purifications and cell cultures.


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