The Tumor Suppressor Interferon Regulatory Factor 1 Interferes with SP1 Activation to Repress the Human CDK2 Promoter*

Rong-Lin Xie {ddagger}, Sunita Gupta {ddagger}, Angela Miele {ddagger}, Dov Shiffman § , Janet L. Stein {ddagger}, Gary S. Stein {ddagger} || and Andre J. van Wijnen {ddagger} ||

From the {ddagger}Department of Cell Biology, University of Massachusetts Medical School, Worcester, Massachusetts 01655 and §CV Therapeutics, Palo Alto, California 94304

Received for publication, February 11, 2003 , and in revised form, April 18, 2003.


    ABSTRACT
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Cell growth control by interferons (IFNs) involves up-regulation of the tumor suppressor interferon regulatory factor 1 (IRF1). To exert its anti-proliferative effects, this factor must ultimately control transcription of several key genes that regulate cell cycle progression. Here we show that the G1/S phase-related cyclin-dependent kinase 2 (CDK2) gene is a novel proliferation-related downstream target of IRF1. We find that IRF1, but not IRF2, IRF3, or IRF7, selectively represses CDK2 gene transcription in a dose- and time-dependent manner. We delineate the IRF1-responsive repressor element between nt –68 to –31 of the CDK2 promoter. For comparison, the tumor suppressor p53 represses CDK2 promoter activity independently of IRF1 through sequences upstream of nt –68, and the CDP/cut/Cux1 homeodomain protein represses transcription down-stream of –31. Thus, IRF1 repression represents one of three distinct mechanisms to attenuate CDK2 levels. The –68/–31 segment lacks a canonical IRF responsive element but contains a single SP1 binding site. Mutation of this element abrogates SP1-dependent enhancement of CDK2 promoter activity as expected but also abolishes IRF1-mediated repression. Forced elevation of SP1 levels increases endogenous CDK2 levels, whereas IRF1 reduces both endogenous SP1 and CDK2 protein levels. Hence, IRF1 represses CDK2 gene expression by interfering with SP1-dependent transcriptional activation. Our findings establish a causal series of events that functionally connect the anti-proliferative effects of interferons with the IRF1-dependent suppression of the CDK2 gene, which encodes a key regulator of the G1/S phase transition.


    INTRODUCTION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Interferon regulatory factors (IRFs)1 are activated by the anti-proliferative actions of interferons through JAK/STAT-mediated signaling mechanisms to inhibit cell growth (13). Genetic evidence suggests IRF1, the prototypical member of the IRF class of transcription factors, functions as a tumor suppressor (4, 5) presumably by regulating cell growth-related target genes (6). There are few experimentally validated IRF1 target genes, and only a subset of these may contribute to the cell growth inhibitory potential of IRF1 (1, 610). To clarify the biological functions of IRF1 as a tumor suppressor, it is necessary to define additional cell growth regulatory genes that are IRF1-responsive.

Our laboratory has shown that IRF1, as well as the closely related protein IRF2 (also known as histone nuclear factor-M (HiNF-M)), can function in the activation of histone H4 gene transcription at the G1/S phase transition through a phylogenetically conserved cell cycle regulatory element (916), which encompasses a canonical IRF consensus sequence (17). A characteristic N-terminal DNA binding domain spanning a winged helix-turn-helix motif (1820) mediates the interaction of IRF factors with their cognate sites. The C-terminal region supports transcriptional enhancement or repression (2123). The transcriptional activity of IRF factors is influenced by post-translational modifications, including phosphorylation and acetylations (2427), as well as by protein/protein interactions with other IRF members and cofactors (1, 10, 2831). The biological role of IRF factors in cell proliferation is reflected by the observation that forced expression of IRF factors perturbs normal cell growth and differentiation (3236). Based on our studies that have revealed cell cycle regulatory roles for IRF proteins in control of histone gene expression at the G1/S transition (9, 10, 12), we have proposed that IRF factors may regulate cell proliferation through transcriptional mechanisms that operate parallel to and/or independent of E2F proteins (9, 10, 12, 35).

Cyclin-dependent kinases (CDKs) represent key factors that regulate major transitions during the cell cycle, and their enzymatic activities are controlled by activating cyclins and CDK inhibitors (CDIs) (37, 38). CDK2 is the critical enzyme controlling the G1/S phase transition and is required throughout S phase. Its serine/threonine kinase activity is activated by cyclins E and A and inhibited by the CDIs p21Waf1/Cip1, p27Kip1, and p57Kip2. The cyclin E and cyclin A promoters are controlled by E2F factors (39, 40), whereas the CDIs appear to be regulated independently of E2Fs. The CDK2 promoter is seruminducible and is known to contain two SP1 binding sites that control basal transcription (41). However, after this initial characterization, the CDK2 promoter has remained unexplored. Because CDK2 activity is required at multiple cell cycle stages, the protein is stringently maintained at constitutive levels throughout the cell cycle. Consequently, the question arises whether control of cell growth may be influenced by anti-proliferative cell-signaling mechanisms that can suppress the basal expression of the CDK2 gene. The principal finding of this study is that the interferon-inducible transcription factor IRF1 interferes with CDK2 gene expression by decreasing the activity of SP1, which is critical for the basal activation of the CDK2 gene. We propose that IRF1 may be a key regulatory node in an IFN-responsive molecular network with positive and negative feedback loops to control cell proliferation.


    EXPERIMENTAL PROCEDURES
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Preparation of Reporter Gene Constructs and Expression Vectors—A panel of constructs containing deletions of the CDK2 promoter fused to the luciferase (LUC) reporter gene has been described previously (41). Construct –2400CDK2/LUC (DSC37) contains the –2.4-kbp promoter region of the human CDK2 gene up to nucleotide +58 bp (i.e. down-stream from the CDK2 mRNA capsite) inserted into the pGL2-basic plasmid (Promega). Additional constructs used in our studies are –683CDK2/LUC (DSC40), –440CDK2/LUC (DSC40{Delta}4–1), –101CDK2/LUC (DSC40{Delta}9–17), and –15CDK2/LUC (DSC40{Delta}10–10) with the first numbers of each construct indicating the retained amount of the CDK2 promoter in base pairs (41).

To delineate the IRF1-responsive element, we prepared two additional CDK2 promoter deletion constructs designated –68CDK2/LUC and –31CDK2/LUC using PCR. To assess the contribution of SP1 to IRF1 responsiveness, we mutated the SP1 site in the –68 CDK2 promoter to yield construct –68(mtSP1) CDK2/LUC. The following forward primers were used to prepare the new constructs: (–68 forward/NheI primer, 5'-atg cta gcC AGG GCG GGG CCT C-3'; –31 forward/NheI primer, 5'-atg cta gcG GAG GCG GCA ACA TT-3'; –68(mtSP1) forward/NheI primer, 5'-tgc tag cCA GGC TCG AGC CTC TGG-3' (mutated nucleotides are underlined). A single reverse BglII primer was used with the above forward primers: 5'-ata gat ctG AAG GCG GAC CCT GGC-3'. The 4xIRF/H4-Site II/CAT plasmid was constructed by inserting an oligonucleotide cassette containing a tandemly repeated IRF binding site (5'-gat ccG CTT TCG GTT TTC AGC TTT CGG TTT CCA GCT TTC GGT TTT CAG CTT TCG GTT TTC a-3'; 5'-gat ctG AAA ACC GAA AGC TGA AAA CCG AAA GCT GGA AAC CGA AAG CTG AAA ACC GAA AGC g-3'; BamHI/BglII overhangs) into the BamHI site of pFP201/CAT (10, 14). All oligonucleotides were synthesized using a 1000M DNA synthesizer (BD Biosciences). All constructs were subject to automated sequencing (ABI 100 model 377) to verify the correct orientation of promoter segments relative to the reporter gene and absence of polymerase chain reaction or chemical synthesis-related mutations. We thank Drs. Tom Maniatis (Harvard University, Boston, MA), Guntram Suske (Philipps-University Marburg, Germany), Gerard Zambetti (St. Jude Children's Research Hospital, Memphis, TN), Ellis Neufeld (Children's Hospital, Boston, MA), and Wade Harper (Baylor College of Medicine, Houston, TX) for kindly providing the following expression constructs: CMV/IRF1 (42), CMV/SP1 (43), CMV/p53 (44), CMV/CDP (45), and CMV/NPAT (46).

Cell Culture and Transfection Experiments—Actively proliferating cultures of NIH3T3 cells were maintained in Dulbecco's modified Eagle's medium (Life Technologies), supplemented with 10% fetal calf serum, 100 units/ml penicillin, 100 µg/ml streptomycin (Sigma), and 2 mM L-glutamine (Sigma) at 37 °C in humidified air containing 5% CO2. Cells were seeded in six-well culture plates (Greiner) at a density of 1.5 x 105 cells/well, and transient transfections were performed 24 h later when cells were ~70% confluent using the SuperFect transfection method (Qiagen). We co-transfected 0.4 µg of each CDK2/LUC reporter gene construct with different amounts of expression gene vectors. The amount of DNA in each well was kept constant by supplementing the transfection mixture with the empty expression vector. Lysates were prepared from cells harvested at different time points after transfection for use in luciferase assays, chloramphenicol acetyl transferase (CAT) assays and/or for Western blot analysis. Experiments using recombinant mouse interferon {gamma} (IFN{gamma}) were carried out by incubating cells with 0–1.0 ng/ml IFN{gamma} (Sigma) beginning 12 h post-transfection. Luciferase activity was analyzed 12–15 h after IFN{gamma} treatment. Each transfection experiment was performed in triplicate, and each experiment was repeated at least three times.

Luciferase and CAT Reporter Assays—Cells were washed twice with 1x PBS buffer at the time of harvest, and lysed with 1x lysis buffer (Promega). Luciferase assays were carried out according to the specifications of the manufacturer using a standard luciferase reporter assay system (Promega), and luminometric units were determined by using the Monolight 2010 luminometer (Analytical Luminescence Laboratory). CAT assays were performed according to standard procedures (47).

Western Blot Analysis—Cell lysates were centrifuged at 14,000 x g at 4 °C for 30 min, and protein concentrations were determined using the Coomassie protein assay reagent (Pierce) according to the manufacturer's instructions. Equal amounts of total cellular protein were mixed with loading buffer (62.5 mM Tris-HCl, pH 6.8,10% glycerol, 2% SDS, 2% {beta}-mercaptoethanol, and bromphenol blue), boiled for 5 min, and subjected to 10% SDS-PAGE. Proteins were transferred to polyvinylidene difluoride membranes (Immobilon-P, Millipore Corp., Bedford, MA). The membranes were saturated with phosphate-buffered saline containing 0.05% Tween 20 (1x PBS-T buffer) and 5% fat-free dry milk for 1 h at room temperature. Blots were then incubated overnight at 4 °C with primary antibodies using the indicated dilutions ({alpha}-IRF1 at 1:1,000, {alpha}-SP1 at 1:2,000, {alpha}-CDK2 at 1;5,000, and {beta}-actin at 1:2,500) (Santa Cruz Biotechnology, Inc.) in 1% fat-free dry milk in 1x PBS-T buffer (milk-PBS-T buffer). After rinsing in milk-PBS-T buffer, blots were further incubated for 1 h at room temperature with the same buffer containing horseradish peroxidase-conjugated secondary antibody (Santa Cruz Biotechnology, Inc.) diluted to 1:8,000–10,000. Blots were then washed three to five times in PBS-T buffer before visualization. The enhanced chemiluminescence (ECL) kit (Amersham Biosciences) was used for the detection of immunoreactive protein bands. To quantitate the endogenous levels of CDK2 in response to forced expression of IRF1, densitometry was performed using the Alpha Imager 2000 densitometer (Alpha Innotech Corp., San Leandro, CA).


    RESULTS
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
IRF1 Represses CDK2 Gene Expression by a Transcriptional Mechanism—The tumor suppressor IRF1 is a principal target of interferon signaling through JAK/STAT to inhibit cell growth. CDK2 activity is one of the major kinases that regulate cell cycle progression at the G1/S phase transition, and the protein is stringently maintained at constitutive levels throughout the cell cycle. We addressed whether IRF1 may transduce the anti-proliferative signals of IFNs by suppressing the basal expression of the CDK2 gene. We expressed IRF1 above its normal levels in fibroblasts and observed a dose-dependent inhibition of endogenous CDK2 gene expression at the protein level (Fig. 1A). Semi-quantitative analysis of our data reveals that the maximal effect of IRF1 on endogenous CDK2 protein levels ranges from 2- to 5-fold in four independent transient transfection experiments (Fig. 1B). This range represents a conservative estimate of the IRF1-dependent reduction of CDK2 levels, because untransfected cells, which continue to express the CDK2 protein unabatedly, generate background signals. Differences in the percentage of untransfected cells in each of the four experiments cause variations in this background level that can account for the range of values in the -fold response. More importantly, in a qualitative sense we observe that IRF1 reproducibly reduces CDK2 protein levels in multiple experiments. For comparison, forced expression of the IRF1-related protein IRF2 does not cause a reduction in the endogenous expression of CDK2 protein (35). Hence, CDK2 levels are selectively decreased in response to forced expression of IRF1.



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FIG. 1.
IRF1 inhibits CDK2 gene expression. A, Western blot analyses performed 24 h after transfection show that endogenous CDK2 expression is inhibited upon increasing IRF1 expression. {beta}-Actin was used as a control for protein loading. The reduction in CDK2 protein levels was consistently observed in multiple experiments, and results of four representative experiments (#1 to #4) are shown. B, quantitative analysis of multiple Western blots shows that IRF1 down-regulates CDK2 protein levels up to 5-fold. The relative protein levels of IRF1 and CDK2 were normalized using {beta}-actin. To facilitate a comparison of relative protein amounts, the level of CDK2 protein in untransfected cells was set as 1.0, whereas the level of IRF1 in cells transfected with 1.6 µg of IRF1 expression vector was set as 1.0. Each experiment was repeated at least three times.

 

To address whether IRF1 influences the levels of CDK2 by a transcriptional mechanism, we co-transfected an IRF1 expression plasmid and a luciferase reporter gene construct under control of the CDK2 promoter. Transfections were performed with different amounts of expression vector, and cells were harvested at various times after transfection (Figs. 2 and 3, as well as data not shown). Our results show that IRF1 reduces CDK2 promoter activity in a manner that is proportional to time after transfection (Fig. 2) and the amount of expression construct (Fig. 3). We conclude that IRF1 inhibits the CDK2 promoter activity in a time- and dose-dependent manner.



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FIG. 2.
Down-regulation of CDK2 transcription in response to IRF1 occurs concomitant with enhancement of H4 promoter activity. NIH3T3 cells were co-transfected with the –683 CDK2/LUC (0.4 µg/well) and 4xIRF/H4-Site II/CAT (0.4 µg/well) reporter gene constructs in the presence of increasing amounts (0–1.0 µg/well) of an IRF1 expression vector. Luciferase and CAT assays were performed at multiple time points after transfection, as indicated. A shows a representative experiment plotted as -fold response upon elevating relative IRF1 levels that reveals the IRF1-mediated down-regulation of CDK2 promoter activity. B presents results from CAT assays with the same cell lysates used in A to show the IRF1-dependent up-regulation of H4 promoter activity. Forced expression of IRF factors does not affect cell viability or growth during the first 24 h.

 


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FIG. 3.
IRF1, but not IRF2, IRF3, or IRF7, selectively inhibits CDK2 gene transcription. NIH3T3 cells were co-transfected with the –683 CDK2/LUC reporter gene (0.4 µg/well) in the presence of increasing amounts of expression vectors for IRF1, IRF2, IRF3, or IRF7. The data show that IRF1 but not IRF2, -3, or -7 reduces LUC activity driven by the CDK2 promoter.

 

We note that, although our data indicate that IRF1 regulates CDK2 transcription, we can not exclude the possibility that CDK2 protein expression may be additionally regulated at post-transcriptional levels in response to IRF1. In addition, it is not possible to directly compare the quantitative effects of IRF1 on endogenous CDK2 protein levels (Fig. 1) with those on transfected reporter genes (Fig. 2) due to the intrinsic differences in the experimental approaches. The main finding of Figs. 1 and 2 is that both CDK2 protein levels and CDK2 promoter activity decline in tandem. This finding indicates that down-regulation of CDK2 protein levels is mediated at least in part by a transcriptional mechanism.

IRF1 is an activator of many genes (1) and we have previously shown that IRF1 activates the cell cycle-regulated histone H4 gene (9, 10). However, the inhibition of the CDK2 promoter by IRF1 suggests that it may function as a repressor. To demonstrate directly that IRF1 can exert bifunctional effects on transcription, it is necessary to establish that IRF1 can mediate both activation and repression under identical biological conditions. Therefore, we co-transfected an IRF1 expression plasmid together with the CDK2 promoter and a histone H4-related promoter each fused to distinct reporter genes (i.e. CDK2/LUC and 4xIRF/H4-Site II/CAT constructs) into the same NIH3T3 cells. Because both reporter gene constructs are present in the same cells, modulations in LUC and CAT activities can be directly compared as a function of elevations in IRF1. Our data show that IRF1 inhibits the CDK2 promoter while simultaneously activating the H4-related promoter in the same population of cells (Fig. 2). These results establish that IRF1 is capable of selectively increasing or decreasing transcription depending on promoter context.

We note that, apart from 4xIRF/H4-Site II/CAT, IRF1 also activates a 4xIRF/H4-Site II/LUC reporter gene (data not shown) (9, 10), indicating that IRF1-dependent transcriptional modulations are observed irrespective of the CAT or LUC reporter gene constructs. Although we could reduce intra-experimental variation by normalizing the LUC and CAT data with a standard Renilla luciferase construct, which we routinely include in our transfection assays, this calculation would affect both reporter genes in the same manner and thus not be informative. The effects of forced expression of IRF1 are clearly evident in the primary data and the LUC and CAT reporters are, respectively, increased and decreased as the amount of IRF1 expression vector is increased. Hence, we are confident that the IRF1-dependent repression of CDK2/LUC and activation of 4XIRF1/H4-Site II/CAT are reproducible properties that are attributable to the promoters present in the respective constructs. More importantly, our observations rule out general squelching of transcription factors as a mechanism for IRF1-mediated repression and provide the basis for the studies described below which are aimed at defining the transcriptional events that are responsible for the inhibitory effect of IRF1 on the CDK2 promoter.

We systematically compared transcriptional inhibition versus enhancement by IRF1 during a time course up to 48 h after transfection to assess the temporal aspects of IRF1-dependent activation versus repression and to determine the earliest stage at which we observe either transcriptional effect. Our data indicate that repression of the CDK2 promoter occurs as early as 8 h after transfection but is more pronounced at 10 h and later time points (Fig. 2A and data not shown). The IRF1-dependent reduction in CDK2 promoter activity is maximal at 48 h. In contrast, IRF1-dependent activation of the H4 promoter is already apparent at 6 h after transfection and remains high at later time points (Fig. 2B and data not shown). The data indicate that the repressive effects of IRF1 on the CDK2 promoter are slightly delayed relative to the activating effects on the histone H4 gene promoter. Furthermore, the time-dependent concomitant increases in repression and activation properties of the IRF1 protein indicates that IRF1 levels remain within a range that supports physiological control of transcription.

IRF1, but Not IRF2, IRF3, or IRF7, Selectively Inhibits CDK2 Gene Transcription—To assess whether the ability of IRF1 to inhibit CDK2 promoter activity is unique or shared with other members of the IRF family, we compared the effects of transfecting different amounts of expression vectors for IRF1, IRF2, IRF3, and IRF7 on CDK2 promoter activity (Fig. 3). In addition, because IRF members may homo- and heterodimerize, we also transfected combinations of IRF1 with IRF2, IRF3, and IRF7 (data not shown). The results indicate that the CDK2 promoter is repressed only by IRF1 and not by the other three IRF proteins (Fig. 3). In addition, co-expression of IRF2, IRF3, or IRF7 does not influence IRF1 repression (data not shown). In contrast to IRF1 (see Fig. 1), IRF2, IRF3, or IRF7 also do not influence endogenous CDK2 protein levels (data not shown). Thus, IRF1-dependent repression of CDK2 promoter activity is not affected by the potential of IRF1 to heterodimerize with other IRF proteins and thus may be directly related to the unique tumor-suppressive properties of IRF1.

Delineation of an IRF1-dependent Repressor Element between nt 68 and31—To define the region of the CDK2 promoter that supports IRF1-specific transcriptional inhibition, we tested a series of deletion mutants of the CDK2 promoter (Fig. 4A) for responsiveness to IRF1. The transfection results indicate that each of the promoter deletion mutants exhibits lower levels of basal transcription in control cells (Fig. 4B), consistent with the loss of putative elements that support CDK2 gene transcription. Deletion mutants up to nt –2400, –683, –440, –101, and –68 are inhibited by IRF1 (Figs. 4B), which is reflected by the ratios of LUC values in cells with elevated IRF1 levels and control cells (Fig. 4C). However, deletion mutants containing sequences up to nt –31 and –15 (Fig. 4, B and C) or that have a deletion between nt –141 to +61 (data not shown) are not responsive to IRF1. Thus, these data indicate that the IRF1-responsive repressor element is located between nt –68 and –31. Inspection of this segment of the promoter indicates absence of a canonical IRF binding site suggesting that IRF1 controls CDK2 transcription through a novel mechanism involving other factors that interact with the CDK2 promoter.



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FIG. 4.
Deletion analysis of the IRF1-responsive element in the CDK2 promoter. A shows a schematic diagram of the CDK2/LUC reporter gene constructs used in this study. Inverted triangles indicate SP1 binding sites, and the asterisks indicate p53 consensus elements. B and C show reporter gene expression results obtained with NIH3T3 cells that were co-transfected with the various CDK2/LUC deletion constructs in the presence or absence of the IRF1 expression vector. B shows relative luciferase values in the absence (light gray bars) or presence (dark gray bars) of IRF1 to permit evaluation of effects of the deletions on basal expression. C shows the -fold repression of each CDK2 promoter construct by IRF1 (expressed as ratio of the LUC values obtained in the presence and absence of IRF1). The luciferase assays reveal that deletion of the segment between nt –68 and –31 results in loss of the IRF1 response. Construct pGL2 represents the promoterless luciferase reporter construct.

 

The CDK2 Promoter Is Repressed by IRF1, p53, and CDP/cut through Distinct Mechanisms—Because the CDK2 promoter does not contain IRF1 binding sites, we postulated that IRF1 either functions through another repressor protein or interferes with the positive activity of an activating factor. However, there is only limited insight into the factors and elements that regulate CDK2 promoter activity (41). To define a molecular framework for the repressive actions of IRF1, we assessed the contributions of a panel of different gene regulatory factors to control of CDK2 promoter activity. Dose-response curves with increasing amounts of expression vectors were established for each of these factors, and adequate doses that result in specific measurable transcriptional effects were used in our experiments (Fig. 5 and data not shown).



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FIG. 5.
Assessment of the contribution of p53, CDP, and NPAT to regulation of the CDK2 promoter. NIH3T3 cells were co-transfected with CDK2/LUC deletion constructs (0.4 µg/well) in the presence of IRF1, p53, CDP, or NPAT expression vectors. A and C show representative experiments that were performed with a fixed effective dose (i.e. 0.4 µg/well) of the indicated expression vectors. Experiments in B and D used increasing amounts of the expression vectors for CDP or NPAT. The results show that p53 reduces activity of the –683 but not the –68 CDK2 promoter (A), whereas CDP represses the –683, –68, and –31 but not the –15 promoter (B and C). For comparison, NPAT does not affect CDK2 promoter activity (D).

 

One of the proteins we tested was p53, which, like IRF1, represents a cell growth inhibitory protein. Both factors are known to interact with the p21waf1/cip1 gene in response to anti-proliferative signals; in each case, induction of the p21 protein inhibits CDK2 kinase activity (7, 48). Therefore, we tested whether, apart from IRF1, p53 can also regulate the CDK2 promoter as a component of a two-pronged growth-suppressive mechanism. It has been reported that the CDK2 promoter contains two putative p53 binding sites (41), but the functional role of p53 on the CDK2 promoter was not previously investigated. Our transfection data reveal that the tumor suppressor p53 represses the –683/CDK2 promoter, which spans two putative p53 binding sites, but not the –68/CDK2 promoter, which lacks these p53 consensus elements (Fig. 5A). Therefore, p53-dependent repression requires elements distinct from those utilized by IRF1.

Similar to IRF1 and p53, the CCAAT displacement protein CDP/cut-like homeodomain protein (CUTL1/cut/cux) is also known to repress transcription of the p21 gene (49). In addition, CDP functions together with IRF proteins in the cell cycle regulation of histone H4 genes (9, 10, 50), as well as in regulation of the myeloid-specific gp91phox gene (45, 51). To assess whether CDP/cut contributes to transcriptional control of the CDK2 promoter, we performed co-transfection experiments in which we analyzed the effects of increasing CDP levels on CDK2 gene transcription (Fig. 5, B and C). The results show that CDP represses the CDK2 promoter in a dose-dependent manner (Fig. 5B) and that repression requires sequences located between –31 and –15 (Fig. 5C). Based on the sequence of the CDK2 promoter (41), the –31/–15 segment contains a CAAT element, and this motif is known to mediate binding of CDP/cut to its target genes (52, 53). The CDP-responsive –31/–15 segment is downstream of the region that mediates the IRF1 effects and thus is not the primary mediator of the IRF1 response.

We also tested the NPAT protein, which represents a key substrate of the CDK2/cyclin E kinase (46). Similar to CDP/cut and IRF1, NPAT is involved in control of histone gene transcription (46), and recent data from our laboratory have demonstrated that NPAT functions as a transcriptional cofactor of HiNF-P, the H4 subtype-specific regulatory protein that mediates up-regulation of H4 gene transcription at the onset of S phase (54). We postulated that NPAT could potentially participate in feedback regulation of CDK2 gene transcription. However, our transfection results indicate that the CDK2/CLN-E-responsive NPAT protein does not influence CDK2 promoter activity (Fig. 5D). Taken together, the results presented in Figs. 4 and 5 establish that IRF1, p53, and CDP/cut, but not NPAT, are capable of transducing inhibitory signals to the CDK2 promoter. This repression occurs in each case through distinct elements, because p53 and CDP/cut repress the CDK2 promoter through sequences that are, respectively, upstream and downstream of the –68/–31 element, which mediates IRF1 repression.

IRF1 Interferes with SP1-dependent Activation of the CDK2 Promoter through an SP1-responsive Element—Previous studies identified three SP1 consensus elements (GC boxes) in the CDK2 promoter centered at approximately nt –160, –90, and –60 (41). Mutation of either the –90 or –60 element within the context of the –101/CDK2 promoter was shown to reduce basal transcription. Both the –90 and –60 elements were experimentally validated by DNase I protection analysis to represent high affinity SP1 binding sites in vitro (41). We extended these previous studies by addressing directly whether SP1 levels are rate-limiting for basal transcription of the CDK2 promoter. Forced expression of SP1 results in a dose-dependent activation of the full-length –2400/CDK2 promoter (data not shown). SP1 activation is also observed with the –68/CDK2 promoter, which contains only one of the three SP1 consensus elements (Fig. 6). However, SP1 activation is not observed when the SP1 promoter element at nt –60 is mutated within the context of the –68/CDK2 promoter (Fig. 6). Thus the SP1 binding site at nt –60 is required and sufficient for the SP1 response of the proximal region (i.e. downstream from nt –68) of the CDK2 promoter.



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FIG. 6.
IRF1 interferes with the SP1-dependent activation of CDK2 gene transcription. NIH3T3 cells were cotransfected with the reporter gene constructs –68 CDK2/LUC (left bars), –68(mt SP1) CDK2/LUC (middle bars), and pGL2/LUC (right bars) as indicated, as well as SP1 or IRF1 expression vectors (0.4 µg/well per construct; presence or absence is indicated by plus/minus signs) to analyze the responsiveness of the CDK2 promoter to SP1, IRF1, or the combination of both. SP1 activates the –68 CDK2 promoter, and co-transfection of IRF1 inhibits the SP1-dependent enhancement of CDK2 promoter activity.

 

Because the –68 to –31 segment lacks a canonical IRF binding site, but contains a functional SP1 binding site, we addressed the hypothesis that IRF1 may counteract SP1 activation of the CDK2 promoter. We co-transfected the IRF1 expression vector and the LUC reporter gene driven by either the wild type or SP1 mutant CDK2 promoter. The key result is that mutation of the SP1 binding site abrogates IRF1-dependent repression (Fig. 6). However, mutation of the SP1 box at nt –60 does not affect the CDP-dependent repression of CDK2 promoter activity (data not shown), because CDP functions through the –31/–15 region of the CDK2 promoter (see Fig. 5C). We conclude that the SP1 binding site at nt –60 is an integral component of the mechanism by which IRF1 mediates inhibition of CDK2 gene expression.

We assessed whether IRF1 represses CDK2 gene transcription by interfering with SP1-dependent activation through the SP1 element. We co-expressed IRF1 and SP1 together with the wild type or mutant –68/CDK2 promoter (Fig. 6). We find that IRF1 inhibits SP1-dependent enhancement of the CDK2 promoter when the GC-box is intact (Fig. 6) and that neither IRF1 inhibition nor SP1 enhancement is observed when the GC-box is mutated (Fig. 6). Hence, IRF1 regulates CDK2 gene transcription by directly suppressing SP1-dependent activation through the GC box in the proximal –68 region of the CDK2 promoter. Although the data establish that the SP1 binding site at –60 is critical when evaluated in the context of the –68/CDK2 promoter, it is likely that the other two SP1 binding sites (at nt –160 and nt –90) also contribute to transcriptional control; these other two sites would probably compensate the GC-box at nt –60 if one mutates in the full-length CDK2 promoter.

Interferon {gamma} mediates an anti-proliferative signal and is known to induce IRF1 levels (1). Therefore we assessed whether interferon {gamma} might elicit its cell growth-inhibiting effects by regulating CDK2 gene transcription through the IRF1-dependent interference with SP1 activity. Cells were transfected with CDK2/LUC constructs and subsequently treated with interferon {gamma}. The data show that interferon {gamma} treatment decreases activity of the wild type but not the SP1 mutant –68/CDK2 promoter (Fig. 7A). In addition, we established that, although forced expression of SP1 increases endogenous CDK2 levels, forced expression of IRF1 reduces the endogenous levels of both SP1 and CDK2 (Fig. 7B; see also Fig. 1). These observed modulations in the expression of endogenous SP1 and CDK2 proteins represent an underestimation of the actual effects, because not all cells are transfected. To test whether IRF1 and SP1 form stable complexes, we performed immunoprecipitation experiments, but precipitates obtained with IRF1 antibodies did not contain detectable levels of SP1 (data not shown). One caveat of this result is that the IRF1-dependent decrease in SP1 levels may preclude detection of SP1 in these precipitates. In addition, a direct interaction between IRF1 and SP1 may not be necessary to influence SP1 levels, because IRF1 may target proteolytic factors that promote SP1 degradation. Taken together, our data suggest that one mechanism by which IRF1 mediates the anti-proliferative effect of interferon {gamma} is by interfering with the SP1-dependent activation of CDK2 gene transcription by decreasing SP1 levels.



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FIG. 7.
Functional roles of interferon {gamma} (IFN{gamma}), IRF1, and SP1 in control of CDK2 gene expression. A, mouse NIH3T3 cells were transfected with the –68 or –68 (mt SP1) CDK2/LUC reporter gene constructs and treated with mouse IFN{gamma} at 12 h after transfection. Luciferase assays show that IFN{gamma}, an inducer of IRF1, represses the wild type but not the SP1 mutant –68 CDK2 promoter. B, Western blot analysis reveals that transfection of increasing amounts of SP1 expression vector (0, 0.5, or 1.0 µg/well) increases SP1 levels and simultaneously increases endogenous CDK2 protein levels. In contrast, increasing amounts of IRF1 expression vector result in elevation of IRF1 levels and cause a concurrent decrease in SP1 and CDK2 protein levels.

 


    DISCUSSION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
In this study, we have obtained several lines of evidence that support the concept that the tumor-suppressive effects of IRF1 may be exerted at least in part by reducing the endogenous protein levels of CDK2, a key regulator of the G1/S phase transition. These data complement previous studies by other laboratories (7), which have indicated that p21, a physiological inhibitor of CDK2 kinase, is activated by IRF1. Thus, one major mechanism that may be operative in the biological function of IRF1 is the potential to mediate a two-pronged effect that can simultaneously decrease the levels of CDK2 protein and increase the levels of its cognate CDK inhibitor p21.

Transcriptional Repression of the CDK2 Promoter by IRF1, p53, and CDP/cut Occurs through Three Distinct Mechanisms—Our data show that IRF1 and p53 suppress the CDK2 promoter through distinct mechanisms, whereas both proteins function as positive regulators of the CDK inhibitor protein p21 through their cognate sites (7, 55). Hence, both tumor suppressor proteins operate through analogous dual growth suppressive mechanisms in which the levels of CDK2 protein are reduced while the levels of p21 are increased. The simultaneous reduction of a cell cycle regulatory kinase and increase in its inhibitor suggests that IRF1 and p53 are highly efficient in targeting cell growth regulatory checkpoints to exert their anti-proliferative activities.

Apart from IRF1 and p53, we show that a third cell growth-related transcription factor (i.e. CDP/cut) is capable of transducing inhibitory signals to the human CDK2 promoter through distinct elements. All three factors have been implicated in transcriptional control of the p21 gene (7, 49, 55). Furthermore, the basal transcription of both the CDK2 and p21 genes is regulated through SP1 binding sites (41, 48, 56). Thus, there is extensive cross-regulation of CDK2 and its cognate inhibitor p21. This shared regulation by the same group of transcription factors may provide an effective mechanism to coordinately activate and attenuate transcription of CDK-related cell cycle genes relative to other groups of regulatory genes (e.g. growth factor receptor/tyrosine kinase cascades, steroid hormone signaling, and phenotype-specific genes).

IRF1 Inhibits the SP1-dependent Activation of the CDK2 Promoter—We have presented several lines of evidence that indicate IRF1-dependent control of CDK2 promoter activity occurs through a novel mechanism. Our results revealed that IRF1 represses the CDK2 promoter in a dose- and time-dependent manner, whereas IRF1 is simultaneously capable of activating other IRF target genes. The IRF1-responsive element we delineated in the CDK2 promoter (nt –68/–31) is devoid of IRF1 recognition motifs. Although IRF1, -2, -3, and -7 are all competent to activate an IRF1-responsive reporter gene, only IRF1 is uniquely capable of inhibiting CDK2 gene transcription. Repression of CDK2 promoter activity does not appear to involve IRF1 heterodimerization with other IRF proteins. We identified at least one SP1 binding site in the CDK2 promoter that is an integral component of the mechanism by which IRF1 mediates inhibition of CDK2 gene expression. Additional data indicate that IRF1 suppresses SP1-dependent activation of CDK2 promoter activity by reducing SP1 levels.

The IRF1-dependent stability of SP1 may be regulated by the activity of proteases that are at least in part transcriptionally controlled. IRF1 is known to activate caspase-8 expression in response to IFN{gamma}/STAT1 signaling, which is a component of the events that sensitize cells for apoptosis (57). Furthermore, IFN{gamma} and/or IRF1 regulate cathepsins B, D, L, and S (5860), which represent cysteine proteases that participate in the lysosomal degradation of proteins and cell death responses. Hence, it is possible that the down-regulation of SP1 levels by IRF1 is related to the activation of proteases that are operative in cell death. However, excessive cell death was not apparent in our studies. Interestingly, both IRF1 and the SP1-related protein SP3 conjugate with the Small Ubiquitin-like Modifier (61, 62), which may affect the activity, stability, and/or subcellular localization of proteins in promyelocytic leukemia (PML) bodies (63).

Pleiotropic Effects of the IRF1-dependent Reduction in SP1 Levels on Other Components of Cyclin-dependent Kinase Complexes—The basal transcription of both the CDK2 and p21 genes is regulated through SP1 binding sites, yet only the promoter of the p21 gene appears to contain IRF binding sites. Thus, IRF1-dependent degradation of SP1 may convert the p21 promoter from a constitutively active SP1-responsive promoter to an IRF1-inducible promoter that responds to feedback mechanisms of the IFN and JAK/STAT signaling pathway. The absence of IRF1 binding sites at the CDK2 promoter ensures that this gene is no longer activated by SP1 without becoming IRF1-responsive. We note that the genes for the CDK2 regulatory subunits, cyclin E and cyclin A, as well as the CDK2 inhibitor p27kip1, are also controlled by SP1 binding sites (6469). Hence, transcription of these genes may be affected by reductions in SP1 levels. Redundancy of SP1 with other transcriptional mechanisms that regulate the promoters of these genes will dictate the extent to which loss of SP1 interactions translates into reduced promoter activity. The expected reduction in the levels of cyclins E and A, together with increased levels of the CDK inhibitor p21 and decreased levels of CDK2, would provide a highly effective mechanism to control CDK2 kinase activity.

Interconnected Autoregulatory Feedback Loops Involving IRF1, SP1, and CDK2 Levels—Recent data indicate that SP1 is required for prolactin activation of the IRF1 gene in T cells (70). Hence IRF1 may attenuate its own protein levels by down-regulating SP1 following the induction of IRF1 in response to extracellular signals. CDK/cyclin A complexes increase SP1 activity (71, 72). Thus, the IRF1-dependent degradation of SP1 levels may also initiate a second autoregulatory feedback loop. We have shown that decreased SP1 protein results in reduced transcription of the CDK2 gene and is expected to reduce expression of the cyclin A gene. The resulting decrease in CDK2/cyclin A protein levels is thus expected to diminish further the transcriptional activity of SP1 and its activation of the CDK2 promoter.

In summary, our findings provide insight into the cell growth inhibitory effects of interferons as well as the normal role of IRF1 as a tumor suppressor. We propose that the up-regulation of IRF1 by interferon {gamma} causes repression of the CDK2 promoter by diminishing the levels of the activating protein SP1. The reduction in CDK2 kinase activity may affect cell growth by inhibiting CDK2-mediated events late during G1 and/or at the G1/S phase transition.


    FOOTNOTES
 
* This study was supported by National Institutes of Health Grant GM32010. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. Back

Present address: Celera Diagnostics, Alameda, CA 94502-7099. Back

|| To whom correspondence may be addressed: Dept. of Cell Biology, University of Massachusetts Medical School, 55 Lake Ave. North, Worcester, MA 01655. Tel.: 508-856-5625; Fax: 508-856-6800; E-mail: andre.vanwijnen{at}umassmed.edu (A. J. v. W.); gary.stein{at}umassmed.edu (G. S. S.).

1 The abbreviations used are: IRF, interferon regulatory factor; STAT, signal transducers and activators of transcription; CDK, cyclin-dependent kinase; CDI, CDK inhibitor; CAT, chloramphenicol acetyl-transferase; IFN{gamma}, interferon {gamma}; PBS, phosphate-buffered saline; CDP, CCAAT displacement protein; nt, nucleotide(s); HiNF, histone nuclear factor. Back


    ACKNOWLEDGMENTS
 
We thank Beata Paluch for assistance with cell culture, Rosa Mastrototaro for providing general laboratory services, and Judy Rask for assistance in the preparation of the manuscript. We thank all the members of our laboratory, and in particular Partha Mitra and Hayk Hovhannisyan, for stimulating discussions.



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