INTRODUCTION

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Previous studies reported that CCAAT/enhancer binding protein  (C/EBP ) can transactivate the human immunodeficiency virus type 1 (HIV-1) long terminal repeat (LTR) in transient transfection analyses and that the LTR contains three binding sites for this protein (39). Since then, evidence regarding the importance of C/EBP family members in HIV-1 replication has steadily increased. Recent studies demonstrated that C/EBP proteins transactivate the HIV-1 LTR in the U-937 promonocytic cell line (19). Furthermore, site-directed mutagenesis indicated that LTR-directed transcription in these cells required one of two functional C/EBP sites. Additional studies indicated that these two C/EBP binding sites were required for replication of an infectious HIV-1 molecular clone in the U-937 cell line as well as in primary cells of the monocyte/macrophage lineage. However, these sites were dispensable for replication of the infectious molecular clone in various T-cell lines and primary T-cell populations (17, 18).

The C/EBP family of proteins includes at least eight different proteins, many of which are important activators of transcription. C/EBP proteins are all members of the b-ZIP family of transcription factors and share a highly homologous carboxy terminus that contains the basic and leucine zipper protein domains. The different C/EBP family members homo- and heterodimerize through their leucine zipper regions and bind to their cognate DNA sequences through the corresponding basic regions. C/EBP family members include both transcriptional activators and repressors. Transcriptional activators include C/EBP  (4), C/EBP  (nuclear factor interleukin-6), (IL-6) (2, 9, 12, 40), C/EBP  (42), C/EBP  (44), and C/EBP-related protein 1 (CRP-1) (42).

While C/EBP proteins are expressed in many human tissues, high levels of C/EBP mRNA and protein expression are limited to only a few cell types, including cells of the myeloid lineage. In fact, C/EBP proteins are intimately involved in the regulation of myelocytic/monocytic gene expression. The promoter elements of many monocyte-specific genes contain C/EBP binding sites, including macrophage inflammatory protein 1 alpha, tumor necrosis factor alpha (32), IL-6 (6, 27, 38), and IL-8 (27, 36). In addition, selected signaling molecules that target cells of the monocyte/macrophage lineage, including lipopolysaccharide (LPS) (21, 30) and IL-6 (2), increase levels of C/EBP-mediated transactivation.

Members of the C/EBP family of proteins interact with other transcription factors to synergistically activate transcription of a number of eukaryotic promoters (24). Specifically, other protein families that commonly interact with C/EBP proteins include Sp, nuclear factor kappa B (NF-B), and activating transcription factor/cyclic AMP response element (CRE) binding protein (ATF/CREB) (16, 22, 23). For example C/EBP  has been implicated as an important factor involved in the liver-specific, cyclic AMP responsiveness of the phosphoenolpyruvate carboxykinase (PEPCK) promoter (33). In this instance, binding of CREB and C/EBP to their cognate sequences, along with activator protein 1, appears to synergistically activate phosphoenolpyruvate carboxykinase transcription.

However, ATF/CREB and C/EBP proteins do not merely influence the activity of one another from their binding sites. Heterodimerization with ATF/CREB family members may also affect C/EBP binding site sequence specificity. ATF-2 and C/EBP  can dimerize at asymmetric binding sites composed of one half of each full-length binding site (35). This type of interaction increases activation from asymmetric binding sites while it decreases transactivation from consensus C/EBP binding sites. Studies have also reported the interaction of C/EBP  and C/EBP-related ATF (C/ATF, a member of the ATF/CREB family) (41). These heterodimers bind to a subclass of asymmetric CRE sites, rather than C/EBP sites. These observations suggest that cross talk between these two protein families may allow for the integration of different hormonal and developmental stimuli involved in regulating gene expression, through transactivation from a variety of unconventional binding sites.

The studies reported herein indicate that the adjoining ATF/CREB and C/EBP sites found in the HIV-1 LTR (Fig. 1A) interact to affect viral gene expression. ATF/CREB site variants that preferentially recruit CREB-1 compared to other family members appear to enhance the binding of C/EBP proteins to an immediately adjacent C/EBP binding site I that exhibits very low affinity for C/EBP proteins. The enhancement of C/EBP binding appears to occur by two mechanisms. First, sequence-dependent heterodimerization between C/EBP and CREB proteins appears to occur to a small degree at a binding site consisting of one half of each of the ATF/CREB and C/EBP binding sites. Recruitment of heterodimers to this site is affected by ATF/CREB sequence variation. Additionally, CREB dimers appear to bind their cognate sequence and recruit C/EBP dimers to an immediately adjacent C/EBP site I that exhibits weak recruitment characteristics. In turn, enhanced C/EBP binding to a weak C/EBP site I was shown to stabilize CREB binding at the ATF/CREB site. In addition, binding of C/EBP proteins to a C/EBP site I that recruits significant amounts of C/EBP protein can lead to increased binding of CREB-1 to an adjacent weakly reactive ATF/CREB site. Finally, sequence variation at the ATF/CREB binding site significantly affects both basal and IL-6-induced LTR activity.

View larger version (41K): [in this window] [in a new window]   FIG. 1.   A C/EBP binding site I variant exhibits very low reactivity for members of the C/EBP transcription factor family. (A) The U3 region of the HIV-1 LTR contains many cis-acting promoter elements that control viral transcription. Included among the many transcription factor binding sites which regulate viral replication are adjacent ATF/CREB and C/EBP binding sites that lie immediately upstream of the tandem NF-B sites. (B) Double-stranded radiolabeled oligonucleotide probes spanning either the 6G or 3T C/EBP binding site I sequence variants were reacted with IL-6-stimulated U-937 nuclear extract. These reactions were conducted in the absence or presence of antibody directed against C/EBP  (lanes 3 and 7) or C/EBP  (lanes 4 and 8). Control rabbit immunoglobulin (CS) was added (lanes 2 and 6) to illustrate the specific nature of supershifted complexes. Arrows to the right indicate supershifted C/EBP complexes, and the bracket to the left identifies the DNA-protein complexes. The EMS reactions were performed in probe excess, and the unreacted free probe is visible at the bottom. The free probe accounted for approximately 75 to 90% of the total probe in each reaction at completion.

	MATERIALS AND METHODS

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Cell culture and nuclear extract preparation. The U-937 (ATCC CRL-1593.2) and THP-1 (ATCC TIB-202) human monocytic cell lines were grown in RPMI 1640 medium supplemented with 10% heat-inactivated fetal bovine serum, antibiotics (penicillin, streptomycin, and kanamycin, each at a concentration of 0.04 mg/ml), L-glutamine (0.3 mg/ml), and sodium bicarbonate (0.05%). The cells were maintained at 37°C in 5% CO₂ at 90% relative humidity. U-937 cells treated with recombinant human IL-6 (Genzyme) were prepared by adding IL-6 (875 U/ml) to 10⁶ cells 24 h prior to the preparation of nuclear extracts. Nuclear extracts were prepared as described elsewhere (13).

Oligonucleotide synthesis and radiolabeling. Complementary single-stranded oligonucleotides corresponding to published C/EBP sequences were synthesized (Macromolecular Core Facility, Penn State College of Medicine, Hershey) and annealed by brief heating at 100°C followed by slow cooling to room temperature. Blunt-ended, double-stranded oligonucleotides were end labeled using -³²P-labeled ATP and T4 polynucleotide kinase as described by the supplier (Promega). The specific activities of the probes used in our electrophoretic mobility shift (EMS) analyses did not generally deviate by a large margin. The average deviation in specific activity between probes across experiments was approximately 20%, which would not solely account for any of the differences in binding patterns observed in the results presented in this report.

EMS analyses. EMS analysis binding reactions were performed using 75,000 cpm of radiolabeled, double-stranded oligonucleotide, 15 to 20 µg of nuclear protein extract, and 1 µg of poly (dI-dC) in a total reaction volume of 15 µl. Experiments using nuclear extract from baculovirus-infected SF9 insect cells that overexpressed CREB-1 included 4 µg of insect extract, generously supplied by Patrick Quinn (Penn State College of Medicine). DNA-protein complexes were allowed to form at 30°C for 30 min and subjected to electrophoresis (30 mA and 200 V) in either a 4 or 5% high-ionic-strength native polyacrylamide gel. For supershift EMS reactions, 1 µl of antibody (2 µg/µl) was added to the reactions after a 20-min incubation at 30°C. The reactions were allowed to proceed for an additional 20 min at 30°C before loading of the gel. A monoclonal antibody recognizing CREB-1 (also provided by Patrick Quinn) was used as indicated. All other antibodies used were obtained from Santa Cruz Biotechnology, Inc.

Protein purification. A polyhistidine-tagged C/EBP  construct (C/EBP -BD-pRSET A) obtained from Edward Maytin (Lerner Research Institute, Cleveland, Ohio) was used to obtain enriched protein extracts. The plasmid was transformed into Escherichia coli strain BL21(DE3)pLysS; transformants were selected using ampicillin (50 µg/ml) and chloramphenicol (35 µg/ml). Expression of the six histidine-tagged protein was induced for 5 h with 1 mM isopropyl -D-thiogalactoside (IPTG) in 1× YT medium. C/EBP  was then purified on nickel-chelating columns using imidazole elution (pRSET Xpress; Invitrogen). Protein purity was assessed by Western immunoblot analysis and silver staining (7, 8, 15, 34).

DNase I footprinting analyses. The probe used in the DNase I footprinting analyses spanned nucleotides +11 to 193 (with respect to the site of transcription initiation) of the HIV-1 (strain LAI) LTR. The probe was generated by radiolabeling the upstream primer (5'-GGT TTG ACA GCC GCC TAG CAT TTC ATC-3') in a kinase reaction using -³²P. The labeled primer and the downstream primer (5'-CCA GAG AGA CCC AGT ACA GGC AAA AAG CAG-3') were then included in a PCR with a plasmid that contained the LAI LTR. The resulting 204-bp radiolabeled DNA product was isolated using a Qiaquick PCR purification kit (Qiagen). The DNase I footprinting reactions were performed using 2,000 cpm of radiolabeled, double-stranded oligonucleotide, six-histidine-tagged C/EBP  (estimated to be 300 ng per reaction), 0.5 µg of poly (dI-dC), and 15 µg of bovine serum albumin in a 50-µl volume. The reaction mixtures were incubated for 3 min with 5 µl of CaCl₂ (2 mM) and MgCl₂ (2 mM) and an amount of a 1:10 dilution of DNase (Promega) predetermined experimentally. The reactions were terminated with a 1 µl volume of a DNase I stop solution (Promega). The proteins were removed by phenol-chloroform extraction, and the DNA was reprecipitated from the reactions, resuspended in formamide loading buffer, and subjected to electrophoresis on an 8% polyacrylamide sequencing gel. The probes were also sequenced by the Maxam-Gilbert chemical sequencing procedure (28), and the sequencing reactions were subjected to electrophoresis in parallel with the DNase I footprinting reactions to verify the positions of protein binding.

Plasmids and site-directed mutagenesis. A PstI/XbaI LTR-containing DNA fragment (~600 bp) derived from the LAI strain of HIV-1 was ligated into a modified pGL3-Basic vector (Promega) to construct the LAI-Luc construct. LAI-Luc was used as a template for site-directed mutagenesis using a QuickChange mutagenesis kit (Stratagene) to construct the chimeric LTRs that contained four ATF/CREB binding site variants next to the low-affinity 3T C/EBP binding site I. The 3T C/EBP variant contains a thymidine substitution at position 3 of the HIV-1 clade B C/EBP site I consensus sequence (Fig. 1B). The parental LAI strain contains the clade B consensus sequence at the ATF/CREB site and the 6G (thymidine-to-guanosine change at position 6) C/EBP binding site (ConB/6G). The four ATF/CREB binding site configurations were designated ATF/CREB variants 1 to 4 (Var1 to Var4). The sequences of the mutants are shown in Fig. 2A. All plasmids used in these studies were sequenced to verify the ATF/CREB and C/EBP binding site sequence configurations (performed in the Penn State College of Medicine Macromolecular Core Facility).

View larger version (61K): [in this window] [in a new window]   FIG. 2.   ATF/CREB binding site sequence variation results in different binding reactivities with respect to CREB-1. (A) Four HIV-1 ATF/CREB sequence variants that differ from the HIV-1 consensus clade B sequence were selected. The ATF/CREB probes (15 bp) were designated as ATF/CREB Var1 to Var4 (divergent nucleotides are underlined). Probes spanning 27 nucleotides that included an ATF/CREB variant and the 3T C/EBP site I sequence were used in subsequent experimentation. The four ATF/CREB probes were used in EMS analyses in which radiolabeled oligonucleotides spanning the ATF/CREB site were reacted with nuclear extract prepared from a baculovirus-infected insect SF9 cell line which overexpressed CREB-1 (B) or the human monocytic U-937 nuclear extract (C). CREB-1 antisera was added (lanes 3, 6, 9, and 12) to demonstrate the presence of CREB in the DNA-protein complexes. Control rabbit immunoglobulin (CS) was added (lanes 2, 5, 8, and 11) to demonstrate the specific nature of supershifted complexes. The asterisk indicates potential ATF-related complexes. Arrows to the right indicate supershifted CREB-1 complexes, and the bracket to the left identifies the DNA-protein complexes. The EMS reactions were performed in probe excess, and the free probe accounted for approximately 75 to 90% of the total probe in each reaction at completion (data not shown).

Transient expression analyses. Exponentially growing cultures were aliquoted at 10⁶ cells in 2 ml of growth medium. For each transfection, 6 µl of FuGENE 6 transfection reagent (Boehringer Mannheim) was dispensed into 94 µl of serum-free medium. After 5 min, DNA was added to the solution, incubated for 15 min, and dispensed dropwise into the cell culture. Cells were transfected with 0.5 µg of firefly luciferase construct in conjunction with 0.04 µg of pRL-TK Renilla luciferase internal control vector (Promega), which is under the control of the herpes simplex virus thymidine kinase promoter. Cells treated with recombinant human IL-6 (Genzyme) received 875 U/ml at the time of transfection. Cells were harvested 24 h after transfection, and dual luciferase assays were performed as described by (Promega). Firefly luminescence was normalized to the Renilla luminescence to control for variability in transfection efficiency. Firefly luminescence (pGL3 constructs) is presented relative to the activity of the parental construct which was set to 1.0 for each experiment. Each value shown represents the average of three independent experiments performed with duplicate samples; error bars indicate the standard deviation.

	RESULTS

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Identification of an HIV-1 C/EBP site I sequence variant that recruits very low levels of C/EBP proteins. Previous studies have demonstrated the critical importance of two HIV-1 LTR C/EBP binding sites (positions 107 to 118 [site II] and positions 167 to 175 [site II] relative to the transcriptional start site) to viral replication within cells of the monocyte/macrophage lineage (17-19). The positions of these two binding sites are illustrated in Fig. 1A. In this report, the functional properties of C/EBP binding site I are examined along with the impact of a directly adjacent ATF/CREB site (22, 23) on the activity of this NF-B-proximal cis-acting element relevant to LTR-directed transcription in cells of the monocyte/macrophage lineage.

HIV-1 LTR ATF/CREB binding site sequence variation leads to alterations in reactivity with CREB-1. Immediately adjacent to C/EBP site I is an upstream ATF/CREB binding site and a downstream NF-B site (Fig. 1A). Previous studies have indicated that sequence variation at the ATF/CREB site impacts ATF/CREB protein binding and HIV-1 LTR activity (22, 23). Furthermore, numerous reports have described synergistic transactivation of different promoters by proteins from the ATF/CREB and C/EBP families (33, 35, 41). As a result, sequence variation within the ATF/CREB binding site was examined with respect to its impact on factor recruitment to C/EBP site I and subsequent C/EBP-dependent transcription.

Sequence variation at the ATF/CREB site alters factor recruitment to the immediately adjacent weak C/EBP binding site I variant. To determine the impact of selected ATF/CREB binding site variants on C/EBP binding to the adjacent cis-acting element, four chimeric ATF/CREB-C/EBP oligonucleotides were employed which contained the weakly reactive 3T C/EBP binding site I variant (Fig. 1B) adjacent to each of the four ATF/CREB sequence variants. We hypothesized that the ATF/CREB variant sites adjacent to the weak 3T C/EBP binding site I would facilitate C/EBP factor binding to the cognate C/EBP binding site if ATF/CREB and C/EBP factors bind in a cooperative manner.

View larger version (49K): [in this window] [in a new window]   FIG. 3.   Probes containing ATF/CREB binding site sequence variants adjacent to a weakly reactive C/EBP binding site can differentially enhance binding of C/EBP nuclear factors derived from monocytic cell lines. (A) Chimeric probes containing the Var1, Var2, Var3, and Var4 ATF/CREB binding sites adjacent to the 3T C/EBP site I were reacted with U-937 (lanes 1 to 4), IL-6-induced U-937 (lanes 5 to 8), and THP-1 (lanes 9 to 12) nuclear extracts. Brackets to the left identify the DNA-protein complexes. (B) Probes containing the Var1 and Var2 ATF/CREB binding sites adjacent to the weakly reactive 3T C/EBP binding site were reacted with nuclear extract from IL-6-induced U-937 cells in EMS analyses. Antisera to C/EBP  (lanes 3, 7, 11, 15, 19, and 23) and C/EBP  (lanes 4, 8, 12, 16, 20, and 24) were added to identify the quantities of these proteins recruited to the DNA-protein complexes. A probe containing the single 3T C/EBP binding site was included (lanes 1 to 4 and 13 to 16) to demonstrate the level of C/EBP recruited to the weakly reactive site alone. Control rabbit immunoglobulin (CS) was added (lanes 2, 6, 10, 14, 18, and 22) to demonstrate the specific nature of supershifted complexes. Arrows to the right indicate supershifted C/EBP complexes, and brackets to the left identify the DNA-protein complexes. The EMS reactions were performed in probe excess, and the free probe accounted for approximately 75 to 90% of the total probe in each reaction at completion (data not shown).

Oligonucleotides containing the ATF/CREB variants exhibit differential abilities to compete for C/EBP proteins derived from U-937 nuclear extract. While EMS analyses (Fig. 3) indicated that the four ATF/CREB variants exhibited different abilities to enhance C/EBP binding to an immediately adjacent weak 3T C/EBP binding site, cold (unlabeled) competitor EMS analyses were performed to quantitate the differences in relative C/EBP recruitment. In these analyses, a radiolabeled oligonucleotide containing the strong Var1 ATF/CREB and weakly reactive 3T C/EBP binding sites was reacted with U-937 nuclear extract. Increasing amounts of unlabeled competitor oligonucleotides Var1/3T, Var2/3T, Var3/3T, and Var4/3T were also added to the reactions. The amount of C/EBP binding (C/EBP  and  combined) was quantitated in each experiment by phosphorimaging analyses. Since Var1/3T appeared to possess the highest reactivity with respect to C/EBP factors (Fig. 3B), it was not surprising that Var1/3T exhibited the highest relative affinity for C/EBP (Fig. 4A), with about a 40-fold molar excess competitor required to reduce the C/EBP complex formation by 50%. However, under most circumstances, competition EMS studies performed with a single protein and the corresponding binding site would result in a 50% reduction in DNA-protein complex formation with the addition of fivefold excess unlabeled homologous competitor oligonucleotide (data not shown). As a result, the larger amount of excess competitor required to obtain a 50% reduction with the chimeric V1/3T probe in homologous competition suggests that complex interactions between the ATF/CREB and C/EBP factors at these two binding sites are required to enhance binding of C/EBP  and .

View larger version (27K): [in this window] [in a new window]   FIG. 4.   ATF/CREB variants adjacent to the weakly reactive 3T C/EBP binding site exhibit differential abilities to compete for C/EBP proteins derived from U-937 monocytic nuclear extract. Radiolabeled Var1/3T probe was reacted with U-937 nuclear extract in the presence of unlabeled competitor oligonucleotide Var1/3T (A), Var2/3T (B), Var3/3T (C), or Var 4/3T (D) in EMS analyses. The amount of remaining radioactive C/EBP complex was quantitated by phosphorimaging analyses. The fold amount of competitor required to decrease C/EBP binding by 50% is illustrated with a dashed line. Each graph is the summary of four independent experiments. The EMS reactions were performed in probe excess, and the free probe accounted for approximately 75 to 90% of the total probe in each reaction at completion (data not shown).

Enhanced C/EBP binding is due in part to heterodimerization with CREB-1 and subsequent binding to a hybrid site consisting of adjacent ATF/CREB and C/EBP half sites. At least three possible mechanisms might explain how CREB proteins enhance the recruitment of C/EBP proteins to an adjacent site (Fig. 5A). First, CREB and C/EBP could heterodimerize and bind to the ATF/CREB binding site (Fig. 5A, model 1). The second possible mechanism also involves heterodimerization between the two families of proteins (Fig. 5A, model 2). In this scenario, CREB-C/EBP heterodimers bind to a hybrid site created by CREB and C/EBP half sites. Heterodimerization between these two families of proteins has been reported previously, as has binding of such heterodimers to unique CREB binding site sequences or hybrid sites consisting of CREB and C/EBP half sites (35, 41). Lastly, CREB homodimers could bind to their cognate sequence and recruit C/EBP dimers to the adjacent weakly reactive C/EBP site (Fig. 5A, model 3).

View larger version (41K): [in this window] [in a new window]   FIG. 5.   Recruitment of different levels of CREB-C/EBP heterodimers and C/EBP homodimers in EMS analyses is dependent on ATF/CREB sequence variation at hybrid binding sites containing adjacent half sites of the ATF/CREB and C/EBP binding sites. (A) Several mechanisms may explain CREB enhancement of C/EBP recruitment. CREB/C/EBP heterodimers may bind to the ATF/CREB binding site (model 1), or CREB/C/EBP heterodimers may bind to a chimeric binding site created by half sites from the ATF/CREB and C/EBP binding sites (model 2). CREB homodimers may bind to the ATF/CREB site and recruit C/EBP dimers to their cognate sequence (model 3). (B) The Var1/3T hybrid half-site probe was reacted with U-937 (lanes 1 to 5) and IL-6-induced U-937 (lanes 6 to 10) nuclear extracts. Monoclonal antisera directed against C/EBP proteins (lanes 3, 4, 8, and 9) and CREB-1 (lanes 5 and 10) were added to the EMS reactions to identify the proteins binding to the hybrid half sites. Control rabbit immunoglobulin (CS) was added to lanes 2 and 7 to demonstrate the specific nature of supershifted complexes. (C) The Var4/3T hybrid half site was reacted with IL-6-stimulated U-937 nuclear extract. Antisera to C/EBP proteins were added to lanes 3, 4, 7, and 8. Control rabbit immunoglobulin (CS) was also added (lanes 2 and 6) to demonstrate the specific nature of supershifted complexes. Arrows to the right indicate supershifted C/EBP complexes (filled) and CREB-1 complexes (open), and brackets to the left identify the DNA-protein complexes. The EMS reactions were performed in probe excess, and the free probe accounted for approximately 75 to 90% of the total probe in each reaction at completion (data not shown). (D) DNase I footprinting analysis was conducted using two 204-bp probes which contained either the Var4 ATF/CREB and 3T C/EBP binding sites within the context of the HIV-1 strain LAI backbone (lanes 1 and 2) or the Var1 ATF/CREB and highly reactive 6G C/EBP binding sites within the LAI backbone (lanes 3 and 4). The probes were reacted with purified six-histidine-tagged C/EBP  (lanes 2 and 4), and regions of DNase I footprinting were compared with probe incubated with DNase I only (lanes 1 and 3). Sequencing ladders of the probes were also included during electrophoresis (data not shown) to confirm the regions of DNase I footprint, and the confirmed binding sites are illustrated to the left.

CREB-1-containing dimers, bound to their cognate sequence, also recruit C/EBP dimers to the weakly reactive C/EBP site I. To further distinguish between the mechanisms illustrated in Fig. 5A, binding to the Var1/3T oligonucleotide probe was compared to binding to a similar probe in which a 10-bp nonsense sequence was placed between the Var1 ATF/CREB and 3T C/EBP binding sites. These probes were reacted with IL-6-stimulated U-937 extracts in EMS analyses (Fig. 6). If CREB-C/EBP heterodimers were bound to the ATF/CREB site (Fig. 5A, model 1), accounting for the majority of enhanced C/EBP binding, the addition of the linker between the two sites should not disrupt enhanced C/EBP binding. However, if CREB dimers recruit C/EBP dimers to the adjacent site (Fig. 5A, model 3), then a 10-bp linker between these sites should disrupt enhanced C/EBP binding.

View larger version (47K): [in this window] [in a new window]   FIG. 6.   EMS analyses with a Var1/linker/3T probe indicate that the majority of enhanced C/EBP binding to Var1/3T depends on CREB dimers binding to their cognate sequences. The Var1/3T (lanes 1 to 5) and Var1/linker/3T (lanes 6 to 10) probes were reacted with IL-6-stimulated U-937 nuclear extract. Antisera directed against C/EBP  (lanes 2 and 7) and C/EBP  (lanes 3 and 8) as well as CREB-1 (lanes 4 and 9) were all used to identify these proteins in the DNA-protein complexes. Control rabbit immunoglobulin (CS) was added to lanes 5 and 10 to demonstrate the specific nature of supershifted complexes. Arrows to the right indicate the supershifted C/EBP complexes (filled) and supershifted CREB-1 complexes (open), and brackets to the left identify the DNA-protein complexes. The EMS reactions were performed in probe excess, and the free probe accounted for approximately 75 to 90% of the total probe in each reaction at completion (data not shown).

Sequence variation at the ATF/CREB site affects C/EBP-dependent transcription. To determine if sequence variation at the ATF/CREB site could impact C/EBP-dependent transcription, chimeric LTRs were constructed for use in transient expression analyses (Fig. 7). The chimeric LTRs contained the variant ATF/CREB binding sites (Var1, Var2, Var3, and Var4) and the weakly reactive 3T C/EBP site within the context of the HIV-1 LTR (strain LAI). For comparative purposes, the parental HIV-1 LAI LTR (containing the ConB/6G ATF/CREB-C/EBP binding site combination) was also used in the transient analyses. Basal activity and IL-6-induced activity are shown in Fig. 7A and B, respectively.

View larger version (18K): [in this window] [in a new window]   FIG. 7.   ATF/CREB sequence variation affects basal and IL-6-induced activity of the HIV-1 LTR with the weakly reactive C/EBP site I. Chimeric LTRs were constructed to contain the ATF/CREB variants adjacent to a weakly reactive 3T binding site within the context of the LAI LTR backbone. The parental LAI LTR (containing the clade B consensus sequence at the ATF/CREB site and the 6G C/EBP binding site) was also included in the analyses. The LTRs were transiently transfected into the U-937 cell line, and the cultures were treated with IL-6 for a 24-h interval. Firefly luminescence was normalized to the Renilla luminescence to control for variations in transfection efficiency. The luciferase activity of each of the chimeric LTRs was normalized to an arbitrary activity level of 1.0 for the parental LAI LTR. Basal (A) activity and IL-6-induced (B) activities were plotted separately. Each transient transfection was done in duplicate, with three independent experiments. The average luciferase count for the LAI LTR was 3,265 ± 1,075, and the average background count was 66 ± 16.

Recruitment of CREB-1 to an ATF/CREB site can be enhanced by an immediately adjacent C/EBP site I that is highly reactive with respect to binding C/EBP proteins. Having demonstrated that CREB-1 binding to a strong ATF/CREB site can lead to enhanced binding to a weak C/EBP binding site, we proceeded to determine the impact of ATF/CREB sequence variation on C/EBP protein binding to a highly reactive C/EBP site and the impact of this binding on CREB-1 binding to the array of ATF/CREB variant sites under study. The probes containing the ATF/CREB variants adjacent to the weak 3T C/EBP site were reacted with IL-6-induced U-937 nuclear extract in EMS analyses, along with similar probes that contained the ATF/CREB variants adjacent to the highly reactive 6G C/EBP site I (Fig. 8) characterized in Fig. 1B. Each of the probes was reacted with control serum (lanes 2, 7, 12, and 17) and antisera directed against C/EBP  (lanes 3, 8, 13, and 18), C/EBP  (lanes 4, 9, 14, and 19), and CREB-1 (lanes 5, 10, 15, and 20). The amount of C/EBP protein recruitment was higher with each of the ATF/CREB variants when placed adjacent to the 6G C/EBP site compared to an adjacent 3T C/EBP site. Thus, even if a highly reactive ATF/CREB site leads to increased binding of C/EBP proteins to a weak C/EBP site, the amount of C/EBP binding is still less than that which is recruited to a very strong C/EBP site I. Interestingly, enhanced CREB binding was observed with Var2 and Var4 when placed adjacent to a strong 6G C/EBP site compared to a weak 3T C/EBP site. This would indicate that strong C/EBP binding at an adjacent site can also lead to enhanced CREB-1 binding to a weak ATF/CREB site. Thus, the binding of proteins from these two families of proteins is intimately connected, and they appear able to enhance the binding of one another, dependent on sequence variation at both sites.

View larger version (70K): [in this window] [in a new window]   FIG. 8.   Highly reactive C/EBP binding sites can enhance binding of CREB-1 to an adjacent weakly reactive ATF/CREB site. Chimeric oligonucleotides containing the Var1 (A, lanes 1 to 10), Var2 (A, lanes 11 to 20), Var3 (B, lanes 1 to 10), and Var4 (B, lanes 11 to 20) ATF/CREB binding sites adjacent to either a weak 3T C/EBP site (A and B, lanes 1 to 5 and 11 to 15) or a strong 6G C/EBP binding site (A and B, lanes 6 to 10 and 16 to 20) were reacted with IL-6-induced U-937 nuclear extract in EMS analyses. Antisera specific for C/EBP  (lanes 3, 8, 13, and 18) and C/EBP  (lanes 4, 9, 14, and 19) were added to the indicated reactions. Control rabbit immunoglobulin (CS) was added (lanes 2, 7, 12, and 17) to demonstrate the specific nature of any supershifted complexes. Arrows to the right indicate supershifted C/EBP complexes (filled) and supershifted CREB-1 complexes (open) and brackets to the left identify the DNA-protein complexes. The EMS reactions were performed in probe excess, and the free probe accounted for approximately 75 to 90% of the total probe in each reaction at completion (data not shown).

	DISCUSSION

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Previous studies have demonstrated that C/EBP-dependent transcription is critical to replication of HIV-1 in cells of the monocyte/macrophage lineage (17, 18). Studies detailed herein indicate that complex interactions occur between two families of transcription factors that interact with an ATF/CREB binding site and the NF-B-proximal C/EBP site I within the HIV-1 LTR, which may affect C/EBP-dependent transactivation in monocytic cell populations. In particular, we have demonstrated enhanced C/EBP factor binding at a naturally occurring weakly reactive C/EBP binding site (3T) due to interactions with CREB-1 (and possibly additional ATF/CREB family members) at an immediately adjacent ATF/CREB sequence. The level of enhanced binding was dependent on the reactivity of the ATF/CREB binding site for CREB-1. The strength of the recruitment of particular ATF/CREB proteins at the cognate sequence affected not only the level of enhanced C/EBP binding but also the identity of C/EBP family members recruited. Furthermore, sequence variation at the ATF/CREB site can impact C/EBP-dependent transactivation (Fig. 7).

For example, ATF/CREB binding sites with relatively high reactivity with respect to binding CREB-1 (Var1 and Var3 [Fig. 2B and C]) enhanced the binding of both C/EBP  and C/EBP  to the greatest extent (Fig. 3B). The weakly reactive CREB binding sites, Var2 and Var4, however, did not exhibit nearly the same level of enhanced binding of C/EBP  to the neighboring weakly reactive C/EBP site I. This indicates that ATF/CREB sites highly reactive with CREB-1 should increase C/EBP-dependent transcription more efficiently than weakly reactive ATF/CREB sites, since C/EBP  is a better transactivator than C/EBP  (data not shown). While ATF/CREB variation did affect C/EBP-dependent transactivation, those with higher reactivities for CREB (Var1 and Var3) did not give the highest levels of activity. Several explanations can account for this discrepancy.

It is possible that ATF family members could also influence C/EBP-dependent transactivation, since previous studies have indicated that these ATF/CREB variants, particularly Var1 and Var2, bind ATF family members to differing degrees with lymphocytic nuclear extract (data not shown). While it was not possible in these studies to supershift any ATF-related complexes, we cannot rule out the possibility that ATF proteins or other CREB-related proteins are recruited to the ATF/CREB variants to different degrees in the monocytic extracts. It is possible that the epitopes recognized by the ATF-specific monoclonal antibodies used in these studies were masked or not present during dimerization, preventing detection in the supershift EMS analyses. Thus, while CREB-1 was shown to affect C/EBP protein recruitment and C/EBP-dependent transcription, CREB-1 may be homodimerizing or heterodimerizing with other yet to be identified ATF/CREB family members. Our competition EMS analyses with Var3/3T (Fig. 4C) also indicate that other CREB-related proteins may be involved in interactions at the ATF/CREB and C/EBP binding sites. With the addition of this relatively high affinity CREB binding site, enhanced C/EBP binding was observed with the labeled Var1/3T oligonucleotide. We hypothesize that Var3/3T recruited additional CREB-related proteins, sequestering these from the Var1/3T probe, allowing additional CREB-1 binding to Var1/3T and enhancement of C/EBP binding.

Similarly, C/EBP-dependent transcription may be affected by the composition of dimers with different ATF/CREB and C/EBP family members. For example, the mobilities of the supershifted C/EBP -containing complexes which bound to the probes containing the ATF/CREB variants adjacent to the 3T C/EBP site appeared to be different, dependent on the ATF/CREB binding site used in the EMS analyses (Fig. 3B). The C/EBP -related complex that was detected with the Var1/3T chimera appeared to have the same mobility as the C/EBP -related complex. Conversely, the C/EBP -related complex that bound to Var3/3T and Var4/3T appeared to have a much faster mobility than the C/EBP -related complex (Fig. 3B). This could be explained by the different sizes of the two C/EBP proteins. C/EBP  is approximately 42 kDa (26, 31, 37), while C/EBP  is a 38-kDa protein (2, 16). Given the mobilities of the different C/EBP -related complexes, the observations suggest that the Var1/3T chimeric probe recruits heterodimers of C/EBP  and C/EBP . Conversely, it appears that the chimeric probes containing the Var3 and Var4 binding sites recruit primarily C/EBP  and  homodimers. The Var2/3T chimeric probe appeared to recruit primarily C/EBP  homodimers, since a supershifted complex containing C/EBP  was difficult to detect. Finally, it is possible that truncated members of the C/EBP family which act as transcriptional repressors are recruited differentially to the sequence variants, thereby complicating interactions between the ATF/CREB and C/EBP proteins.

While synergistic interactions between the ATF/CREB and C/EBP protein families have previously been observed (33, 35, 41), they have not been defined within the context of the HIV-1 LTR. The interaction between the two protein families and the HIV-1 LTR appears to occur via a combination of mechanisms. A small fraction of the enhanced C/EBP  binding may occur via homodimerization or dimerization with CREB-1 (depending on the ATF/CREB variant configuration). These heterodimers are then able to bind to a hybrid binding site created by adjacent half sites from the ATF/CREB and C/EBP binding sites (Fig. 5B and C). While the level of C/EBP recruited via this mechanism was small with the Var1, Var2, and Var3 ATF/CREB binding sites, significant levels of C/EBP proteins were recruited when the Var4 half site was placed adjacent to the 3T half site. In this case, rather than recruiting CREB-C/EBP heterodimers, the hybrid binding site Var4/3T led to increased C/EBP dimer recruitment (Fig. 5C and D). Most likely, this mechanism of recruitment explains the high level of LTR activity observed with the Var4/3T chimeric LTR upon IL-6 induction, with the hidden C/EBP site recruiting more C/EBP factors than are recruited to a low-affinity C/EBP site during enhancement of C/EBP binding by a strong ATF/CREB site.

Interestingly, the high levels of C/EBP recruitment were not observed when the two full-length binding sites were adjacent to one another (Fig. 3B). It is possible that under certain conditions, CREB-1 binding to its cognate sequence prevents access to this hybrid binding site. Under conditions where the ATF/CREB binding site is unoccupied, perhaps it is then possible to observe enhanced recruitment of C/EBP proteins at the adjacent ATF/CREB and C/EBP half sites. Alternatively, in instances where C/EBP proteins undergo modification (for example, following IL-6 stimulation), perhaps increased C/EBP affinity for the hybrid binding site is greater than the affinity of CREB-1 for its cognate sequence, forcing the displacement of CREB-1.

Thus, the composition and quantity of proteins recruited to the hybrid sites created between the adjacent ATF/CREB and C/EBP binding sites can fluctuate greatly. Under most instances examined, the majority of C/EBP  enhancement as well as the enhanced binding of C/EBP  appears to occur by a second mechanism. In this case, dimers containing CREB-1 appear to bind to their cognate ATF/CREB binding site and recruit C/EBP dimers to the weakly reactive 3T binding site (which does not efficiently recruit these proteins on its own).

Interactions between ATF/CREB and C/EBP proteins may involve direct contact between these factors or an intermediary protein that links factors bound to these two sites. We hypothesize that CREB-1 probably enhances C/EBP binding using CBP as a molecular bridge. A recent study demonstrated a similar cooperation between Myb and C/EBP  (29). In this case, Myb bound to its cognate DNA sequence and recruited C/EBP proteins to an adjacent site via interactions with p300, a coactivator protein homologous to CBP. Myb binds to p300 through the CREB binding domain on the p300 protein. The p300 protein then acts as a bridge between Myb and the adjacent C/EBP binding site, as p300 also possesses a C/EBP binding domain. We propose that a similar mechanism may be involved between the ATF/CREB and C/EBP binding sites in the HIV-1 LTR. In this scenario, CREB dimers bind to their cognate binding site and recruit CBP, the major coactivator for CREB. CBP then forms a bridge between the two binding sites and leads to enhanced binding of C/EBP proteins at the adjacent C/EBP site I, due to interactions between C/EBP and the E1A domain of CBP. We have found support for this hypothesis in EMS analyses that indicated that disruption of p300/CBP binding (by the addition of antisera reactive for CBP and p300) caused a decrease in the amount of C/EBP proteins recruited to Var1/3T, with a concomitant increase in the level of CREB-1 recruited (data not shown). Future studies must be conducted to determine if ATF/CREB-enhanced binding of C/EBP is dependent on CBP or p300. If this is the case, it must then be determined whether this interaction is specific for C/EBP , or if it is applicable to all C/EBP family members. We have been unable to demonstrate enhanced binding of six-histidine-tagged C/EBP in the presence of six-histidine-tagged CREB-1 using DNase I footprinting analysis (data not shown). We believe that this is due to the requirement for CBP/p300 as a molecular bridge leading to enhanced C/EBP binding. Future studies will address the requirement for CBP/p300 in ATF/CREB-dependent enhancement of C/EBP binding and the necessary phosphorylation states of the proteins involved.

It is interesting that CREB-1 binding also appeared to be increased with enhanced C/EBP binding. When the high-affinity Var1 ATF/CREB site was immediately adjacent to the weakly reactive C/EBP site, CREB binding was threefold higher than when the CREB site was separated from the C/EBP site by 10 nucleotides. Thus, it appears that CREB-1 enhances C/EBP binding to the weakly reactive 3T site, which in turn enhances CREB-1 binding. If CBP is responsible for much of the enhanced C/EBP binding, it is possible that the binding of CREB-1 and C/EBP to their respective domains on CBP forms a much more stable complex than does CREB-1 binding to CBP alone. Future studies will examine this hypothesis in detail.

However, enhancement of C/EBP binding by CREB-1 appeared limited to instances when highly reactive ATF/CREB binding sites were adjacent to a weakly reactive C/EBP site I. When a highly reactive 6G C/EBP site I was placed adjacent to the ATF/CREB binding site variants, strong C/EBP binding was observed above the enhanced recruitment to the weak 3T site (Fig. 8). This indicates that while CREB binding can lead to enhanced C/EBP recruitment, the levels of protein binding were still lower than the amounts of protein recruited to a very strong C/EBP site I. Interestingly, CREB-1 binding to a weak ATF/CREB site can also be enhanced by C/EBP binding to a strong C/EBP binding site (Fig. 8). This indicates that the recruitment of proteins to these two sites is highly dependent on sequence variation at both sites and that binding of proteins from these two families of proteins is highly interrelated and interdependent.

In summary, complex interactions appear to occur between ATF/CREB and C/EBP in the context of the HIV-1 LTR. C/EBP and CREB dimers impact one another in a manner dependent on the strength of the two binding sites, which is governed by sequence variation at each site. Given the integral role that NF-B and Sp family members play with respect to HIV-1 replication and the immediate proximity of the NF-B and Sp binding sites to the ATF/CREB and C/EBP sites, an important focus of future studies will be to determine the impact of NF-B and Sp binding on ATF/CREB and C/EBP within the context of replication within cells of the monocyte/macrophage lineage. Future studies will continue to examine the intricate biochemical interactions between the NF-B, ATF/CREB, and C/EBP transcription families, the coactivators CBP and p300, the phosphorylation state of the involved proteins, and their role in regulating HIV-1 LTR-directed transcription in cells of the monocyte/macrophage lineage.