INTRODUCTION

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The initiation of transcription of genes by RNA polymerase II is usually controlled through complex transcriptional regulatory regions containing multiple binding sites for sequence-specific upstream transcription factors (74, 88). Overall transcriptional responsiveness is determined by cooperative and competitive interactions between the DNA-bound factors that are often dependent upon the precise juxtaposition of DNA binding sites (44). The regulatory potential of individual transcription factors can be influenced indirectly through the manipulation of DNA and/or chromatin structure (6, 8, 55, 88, 91). The precise arrangement of the transcription factor binding sites is also important for the cooperative interactions of sequence-specific transcription factors with transcriptional coactivators and the basal transcription machinery (43, 53, 62, 80, 94).

In many instances, transcriptional cooperativity also correlates with direct protein-protein interactions between individual sequence-specific transcription factors. Often, protein-protein contacts between heterologous factors stabilize DNA binding or alter the sequence specificity of binding. Thus, DNA-bound serum response factor is required for the formation of a ternary complex which includes serum response factor accessory protein 1 (SAP-1) (90); the sequence-specific DNA binding of DNA-dependent protein kinase is mediated through its association with DNA-bound Ku autoantigen (30), and the interaction of herpes simplex virus protein 16 (VP16) with host cell factor and the POU homeodomain protein octamer transcription factor 1 (Oct-1) alters the DNA sequence specificity of Oct-1 DNA binding (42, 98). Indeed, the sequence-specific DNA binding of several homeodomain proteins has been demonstrated to depend on stabilizing interactions with other sequence-specific transcription factors, including Exd, Ubx, Pbx, Hox, Ftz-F1, Ear3, and Arp1 (16, 34, 36, 71, 95, 96, 105).

There have also been a number of recent reports of sequence-specific transcription factors effectively functioning as transcriptional coactivators to potentiate activation of transcription by binding to other DNA-bound factors without directly contacting DNA themselves. For example, the glucocorticoid receptor (GR) has been demonstrated to act as a coactivator of Stat5 in prolactin-responsive cells (82). Similarly, GR and NF-IL6 appear to interact in a manner that allows each factor to potentiate transcriptional activation by the other from either a glucocorticoid response element (GRE) or an NF-IL6 DNA recognition sequence (63). The atypical homeodomain protein prospero enhances the DNA binding of the homeodomain proteins Dfd and HoxA5 in the absence of prospero DNA binding sites (35). In contrast, protein-protein binding can also restrict transcriptional activation potential. Thus, the Stat5-GR interaction appears to repress the activation of transcription through a GRE and prospero inhibits DNA binding by Eve (35, 82).

GR is a ligand-activated nuclear hormone receptor (7) that exists in the cytoplasms of unstimulated cells in an inactive complex with heat shock proteins and immunophilins (72). Hormone binding induces dissociation of the receptor-heat shock protein complex and rapid transfer of the free, transcriptionally active receptor to the nucleus, where it binds with high affinity to GREs (5, 83) as a homodimer to regulate transcription through interactions with transcriptional coactivators such as steroid receptor coactivator and CREB binding protein (14, 82). DNA binding of each GR monomer is mediated through two Cys4 zinc fingers that are highly conserved within the nuclear receptor superfamily (48).

Studies of the mouse mammary tumor virus (MMTV) promoter-proximal regulatory region have revealed two ways in which GR can influence the ability of other sequence-specific transcription factors to regulate transcription (7). This region of the MMTV long terminal repeat (LTR) encodes binding sites for nuclear factor 1 (NF1) (9, 11, 59) and octamer transcription factors (8, 10, 89) in addition to a complex GRE (15, 78). However, transcription from the MMTV promoter-proximal regulatory region is tightly controlled by hormone, with NF1 and Oct-1 having little effect on transcription in the absence of steroid (12, 65). Prior to stimulation, the MMTV LTR is packaged into a series of precisely positioned or phased nucleosomes that appear to specifically exclude NF1 from the MMTV promoter (2, 3, 64, 67, 70, 102). Upon hormone treatment, the binding of liganded GRs to the GRE is proposed to initiate a remodelling of the chromatin that makes the promoter accessible to NF1 and leads to the occupancy of the MMTV NF1 binding site in vivo (3, 8, 21, 70). Support for this hypothesis comes from a series of in vitro experiments which have demonstrated that GR and NF1 bind to the MMTV LTR and activate transcription independently on chromatin-free templates (8, 40). Further, on transiently transfected plasmid DNAs, which are not precisely packaged into chromatin, NF1 binding to the MMTV LTR occurs constitutively and is not affected by GR (3, 50).

In contrast, DNA binding and the activation of MMTV transcription by GR and Oct-1 have been shown to be highly cooperative both in vivo and in vitro (8, 91). Although the MMTV octamer motifs occur in vivo in linker DNA between two nucleosomes (91), and thus are expected to be more accessible than the NF1 binding sites, binding to the octamer motifs in vivo was also observed to be strictly hormone dependent (91). The binding of Oct-1 to the MMTV LTR in vitro was also dependent on GR (8). Specifically, addition of GR decreased the concentration of octamer factor required to saturate the octamer motifs in in vitro footprinting experiments (8). Further, transcriptional regulation of chromatin-free DNA templates by Oct-1 and GR was highly cooperative. Preliminary experiments have indicated that GR and Oct-1 may bind directly in solution through an interaction requiring the Oct-1 homeodomain (45). However, this interaction does not appear sufficient for either GR or Oct-1 to act as a transcriptional coactivator to potentiate transcription in the absence of octamer motifs or GREs. Rather, there is some evidence to suggest that GR may antagonize the activation of transcription by Oct-1 from regulatory regions that lack GR binding sites (45, 101).

Octamer transcription factors bind through their POU domains (100) to an 8-bp DNA recognition sequence known as an octamer motif (27, 97). The POU domain is a bipartite DNA binding domain (DBD) comprised of a homeodomain and a POU-specific helix-turn-helix motif (41). Binding of the two domains to DNA is highly cooperative. Oct-2 is highly similar in its POU domain to Oct-1 but has a distinct transcriptional regulatory potential (86) and does not interact with VP16 (46). Oct-1 and Oct-2 are constitutively active in cells in which they are expressed. Oct-1 is a ubiquitous protein, while Oct-2 is expressed mainly in lymphoid cells (20, 85). Like Oct-1, Oct-2 appears to activate transcription synergistically with GR (101). Furthermore, this transcriptional synergism also seems to result, at least in part, from the cooperative binding of GR and Oct-2 to DNA (101).

In this study, we have investigated the mechanism of transcriptional synergism between GR and Oct-1 or Oct-2 (Oct-1/2) by examining the molecular basis for their direct binding. Our results indicate that the POU domains of Oct-1 and Oct-2 bind to the DBD of GR in solution. We identified two point mutations in the DNA-contact -helix in the C-terminal zinc finger of GR that individually prevented Oct-1/2 binding to GR in vitro and in vivo. The result of GR-Oct-1/2 binding in transiently transfected cells was a striking recruitment of the octamer factor to binding sites adjacent to GR binding sites, and this recruitment correlated directly with a dramatic increase in reporter gene transcription. Indeed, recruitment of Oct-2 to a promoter by a GR peptide unable to significantly activate transcription on its own resulted in transcriptional activation approximately 100-fold higher than could otherwise be achieved by ectopic expression of Oct-2 alone. Intriguingly, addition of a GRE to protein incubations was sufficient to disrupt preformed GR-Oct complexes. Our data support a mechanism for transcriptional cooperativity in which GR directly recruits Oct-1/2 to glucocorticoid-responsive promoters. However, the nature of the GR-Oct-1/2 interaction seems to ensure that Oct-1 and Oct-2 do not act as transcriptional coactivators of DNA-bound GR on promoters lacking octamer motifs.

	MATERIALS AND METHODS

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Plasmids. The plasmids pGALO (77), pNLVP16 (23), and pG5E1BCAT (54) have been previously described, as have the GR and Oct plasmids GRWT (pRDN93) (58), X795, X616, X568 (76), and pCGNOCT-2 (86). Most of the plasmids containing point mutations in the GR DBD have also been described previously (79) as has the MMTV CAT reporter plasmid pHCWT (13). Plasmids used for in vitro translation include pSP6Luc (Promega) and pET11dCREB (24). The plasmid encoding the G504R point mutation (pT7G504R) was constructed by substituting the XhoI/PstI (blunted) GR fragment from pVAG504R (69) into pT7X556 (29) (XhoI/SacI [blunted]), to produce a plasmid that expresses an RNA encoding amino acids (aa) 407 to 523 of rat GR under the control of the T7 promoter. The plasmid with an L501P mutation in the wild-type (WT) GR full-length sequence (GR_WT) was constructed by a site-directed mutagenesis strategy and then subcloned into p6RGR (66). Vectors expressing GR_WT and GR with the L501P mutation (GR_L501P) with N-terminal c-myc tags (pMTG-GR and pMTG-GRL501P) were created by cloning the BglII/SmaI 350-bp fragment from pCRIIMTG (a gift from J. Bell, University of Ottawa) and the MscI/BamHI GR fragments from p6RGR into pTL2 (provided by M. Petkovich, Queen's University) digested with BglII and BamHI. GR_WT, GR_L501P, and GR_C500Y DBDs fused to the Gal4 DBD were constructed by inserting NdeI/SacI fragments from the appropriate pT7-X556 vector (79) in frame into pGALO 3' to the Gal4 DBD. The plasmid expressing the Oct-1 POU domain fused to the VP16 transcriptional activation domain was prepared by cloning a PCR-amplified Oct-1 fragment encoding aa 265 to 444 into pNLVP16. pGSTOct-2POU was cloned by inserting a PCR-amplified DNA fragment encoding aa 186 to 367 of Oct-2 (20) into pGEX 2T (Pharmacia).

Cell culture, transfections, and chloramphenicol acetyltransferase (CAT) assays. CHOK1 cells (American Type Culture Collection, Manassas, Va.) were maintained in -minimal essential medium supplemented with 10% fetal bovine serum (Life Technologies, Burlington, Vt.). HeLa and Sf7 cells were maintained in Dulbecco's modified Eagle's medium supplemented with 10% fetal bovine serum.

6

In vitro binding to GST fusion proteins. Glutathione S-transferase (GST) fusion proteins were expressed and purified on glutathione-Sepharose essentially as described previously (46). GR peptides were in vitro translated in the presence of [³⁵S]methionine with the coupled transcription-translation TNT reticulocyte lysate system (Promega). Steroid binding was accomplished by addition of 10⁶ M Dex to the in vitro-translated GR for at least 2 h at 4°C followed by incubation at 25°C for 25 min as previously described (25). The association of GR with heat shock proteins was stabilized by the addition of 20 mM MoNa₂O₄ (49). The levels of binding of the in vitro-translated GRs to the GST fusion proteins were determined essentially as described previously (46). Briefly, equal amounts of in vitro-translated proteins were incubated with 0.5 µg of immobilized GST fusion protein in 200 µl of binding buffer (20 mM HEPES [pH 7.9], 60 mM KCl, 12% glycerol, 1.5 mM EDTA, 1 mM dithiothreitol [DTT], 0.15 mM phenylmethylsulfonyl fluoride, 0.1% Nonidet P-40) for 90 min at 4°C. Following four washes with binding buffer, the proteins retained on the affinity matrix were eluted in sodium dodecyl sulfate (SDS) sample buffer and resolved by SDS-polyacrylamide gel electrophoresis (PAGE). Levels of binding were compared to those of 10% of the in vitro-translated proteins added to the incubations.

Peroxide treatment of the GR. The GR DBD peptide X556 was expressed in BL21 (DE3) and partially purified as previously described (29). X556 was approximately 10% pure, as estimated by Coomassie blue staining of SDS-polyacrylamide gels.

Immunoprecipitations and Western blot analysis. Western blotting was performed with Immobilon-P membranes (Millipore), and proteins were visualized by enhanced chemiluminescence (Amersham).

6

In vivo footprinting of transiently transfected plasmids. Nucleus preparation and  exonuclease analysis were performed essentially as described previously (61). A total of 1.5 × 10⁵ nuclei were used for each  exonuclease analysis. Restriction enzyme digestion of the nuclei was used to create specific entry points for exonuclease digestion. Nuclei from cells transfected with pHCWT were digested with BamHI, pBSGREOCTd was digested with SmaI, and pBSGALOCT and pBSGALIAP were digested with XhoI. Each sample was simultaneously digested with 100 U of restriction enzyme and 15 U of  exonuclease (Life Technologies) for 15 min at 30°C. Reactions were stopped with SDS-EDTA, and the DNAs were purified by proteinase K digestion and phenol-chloroform extraction.

Nuclear extracts and EMSA. Nuclear extracts from transiently transfected cells were prepared by a micropreparation procedure (1) from confluent 60-mm-diameter plates. In all extracts used for EMSA, levels of transiently expressed proteins were first verified by Western blotting. ³²P-labelled oligonucleotides for GALOCTd and GALIAP have been described above. The GAL_mtOCT oligonucleotide had a 2-bp mutation (underlined) that is said to eliminate Oct-1/2 binding (19) (5'-CGGAG TACTG TCCTC CGGTA CCTGT CGGCA AATAA GGT-3'). Nuclear extracts (1 µg) were preincubated alone or in combination for 4 h at 4°C. This incubation was followed by addition of 2 ng of ³²P-labelled oligonucleotides, 1 µg of poly(dI-dC), 1 µg of bovine serum albumin, and 100 ng of competitor oligonucleotides, as indicated in the figures, for 20 min at room temperature in 12 mM HEPES (pH 7.9)-12% glycerol-60 mM NaCl-0.12 mM EDTA. Protein-DNA complexes were resolved on 4% polyacrylamide (acrylamide-bisacrylamide [39.5:1]) gels in 0.5× Tris-borate-EDTA.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

The GR DBD directs binding of GR to the Oct-1 POU domain in vitro. To begin a detailed examination of the potential for the GR to bind directly to Oct-1/2, we expressed the POU domain of Oct-1 as a GST fusion protein (46). A previous report implicating the POU homeodomain of Oct-1 in GR binding and the lack of similarity between Oct-1 and Oct-2 outside of the POU domain suggested this region as the likely target for GR binding (45, 86). In a first series of experiments, we tested the ability of in vitro-translated rat GR fragments to bind to the GST-Oct-1 POU domain fusion protein (Fig. 1). In vitro-translated GR is incorporated into a heat shock protein-containing multiprotein complex that closely mimics the complexed state of unliganded GR in the cytoplasm (22). In addition to stabilizing the ligand binding domain in a conformation able to accept ligand, association of GR with these accessory proteins masks DNA binding, nuclear localization, and other functions of GR (72). Addition of the synthetic steroid Dex to in vitro-translated receptor results in the release of the heat shock proteins from the liganded receptor (22).

View larger version (26K): [in this window] [in a new window]   FIG. 1.   Specific binding of the GR to the POU domain of Oct-1 in vitro is abrogated by C-terminal truncation into the DBD. (A) Schematic presentation of in vitro-translated rat GR fragments used in panels B and C. The positions of the DBD, ligand binding domain, and heat shock protein binding domains of GR are diagrammed. (B) In vitro-translated Dex-treated GR, CREB, and firefly luciferase (Luc.) were tested for binding to GST-Oct-1 POU by a pulldown assay. Levels of binding (lanes 1 to 3) were compared to those of 10% of the receptors added to the incubations (lanes 4 to 6). The migrations of molecular mass markers are indicated to the left of the autoradiographs. (C) In vitro-translated GR fragments were tested for binding to GST-Oct-1 POU. GRWT and X795, which contain intact ligand binding domains and which were complexed with heat shock proteins in the absence of ligand, were tested for Oct-1 POU binding in both the presence (+) and absence () of bound steroid (Dex). SDS-polyacrylamide gels were exposed equally to compare specific levels of binding (lanes 1 to 6) to those of 10% of the in vitro-translated proteins added to the incubation (lanes 7 to 12). (D) In vitro-translated full-length and C-terminally deleted GRs produced by transcription of a restricted DNA template were tested for binding to immobilized recombinant GST-Oct-1 POU. Bound untreated and Dex-treated full-length receptors are shown in lanes 1 and 2, respectively, while the C-terminal truncations are shown in lanes 3 to 5. Levels of binding of proteins are compared to levels of binding of 10% of the input proteins shown in lanes 6 to 10.

View larger version (43K): [in this window] [in a new window]   FIG. 2.   The mutations C500Y and L501P in the GR DBD eliminate binding to GST-Oct-1 POU in vitro. (A) Schematic summary of the DNA binding domain of the rat GR DBD showing the position of the zinc-coordinating cysteines and the two -helices that contact DNA. (B) The in vitro-translated GRWT DBD (aa 407 to 568) (lanes 8 and 19) and specific point mutation-containing peptides (all of which were in the aa 407 to 556 GR backbone except G504R, which was in the aa 407 to 523 backbone) (lanes 2 to 11) were tested for binding to GST-Oct-1 POU (lanes 2 to 11) in comparison to that of X616 (lanes 1 and 12), as described for Fig. 1.

View larger version (32K): [in this window] [in a new window]   FIG. 3.   Removal of zinc from the GR DBD has no effect on binding to GST-Oct-1 POU. (A) The effects of peroxide-EDTA treatment, which strips the coordinated zinc from the GR DBD, and the subsequent partial reconstitution of zinc coordination on the binding of bacterially expressed X556 to a GRE was evaluated by EMSA. (B) Effects of the same treatment described for panel A on the binding of in vitro-translated X616 to GST-Oct-1 POU.

Point mutations in the GR DBD prevent the binding of GR to Oct-1/2 in vivo. To determine the involvement of residues in the -helix extending from the second finger of the GR DBD in the binding of full-length GR to WT Oct-1/2 in solution, cellular extracts were prepared from murine Sf7 fibroblasts stably transfected to express similar levels of full-length WT and L501P GRs with N-terminal c-myc tags. The binding of full-length, in vitro-translated, Oct-1 and Oct-2 to the GRs in extracts prepared 1 h after glucocorticoid hormone treatment was determined by examining the amounts of Oct-1 and Oct-2 immunoprecipitated with an antibody to the c-myc tag (Fig. 4). Both Oct-1 and Oct-2 were efficiently immunoprecipitated with GR_WT, but neither protein was detected above background in GR_L501P immunoprecipitates. Thus, both Oct-1 and Oct-2 were observed to bind full-length, liganded GR and this binding was completely abrogated by the L501P point mutation in the GR DBD.

View larger version (30K): [in this window] [in a new window]   FIG. 4.   An L501P substitution in full-length GRWT eliminates binding to full-length WT Oct-1 and Oct-2. GRWT (lanes 2 and 6) and GRL501P (lanes 3 and 7) with N-terminal c-myc tags in nuclear extracts of stably transfected CHOK1 fibroblasts were tested for binding to in vitro-translated full-length Oct-2 (A) and Oct-1 (B) by immunoprecipitation with anti-myc antibody 9E10. Binding to immunoprecipitated control extracts lacking myc-tagged GR is shown in lanes 4 and 8. Levels of binding were compared to those of 10% of input Oct-2 and Oct-1 (lanes 1 and 5, respectively) and were quantified by exposure of the SDS-polyacrylamide gels to a storage phosphor screen. The relative counts are displayed beneath the lanes. (C) A Western blot of the immunoprecipitated GRWT, GRL501P, and control nuclear extracts with BUGR2, a GR-specific antibody, demonstrates that equal amounts of the two receptor forms were immunoprecipitated from the extracts.

View larger version (22K): [in this window] [in a new window]   FIG. 5.   Two-hybrid analysis of the binding of the GR DBD to the Oct-1 POU domain in CHO cells as reflected by the activation of pG5E1bCAT transcription. Gal-GRWT, Gal-GRL501P, or the Gal4 DBD (GalO) were coexpressed with the VP16 activation domain alone (left) or tethered to the POU domain of Oct-1 (right). The means and standard errors of the means of results of five independent transfections are shown. Western blot analysis indicated that GalO, Gal-GRWT, and Gal-GRL501P were expressed at the same level (73). Similar results were also obtained with HeLa cells (73).

GR recruits octamer factors to adjacent octamer motifs in vivo. DNA binding experiments have shown that, in vitro, GR decreases the concentration of octamer factor required to saturate binding sites adjacent to GREs (8). Further, we have demonstrated that the levels of occupancy of the MMTV promoter octamer motifs by Oct-1 in vivo on chromatin closely paralleled the levels of binding of GR to the MMTV GREs (91). However, in this instance, GR binding to the MMTV promoter induced a rearrangement of chromatin structure that may have promoted Oct-1 binding by increasing the accessibility of the octamer motifs. Thus, it was not possible in these experiments to distinguish the extent to which occupancy of the octamer motifs resulted from the cooperativity in DNA binding observed in vitro between Oct-1 and GR.

View larger version (70K): [in this window] [in a new window]   FIG. 6.   GR binding recruits Oct-2 to octamer motifs adjacent to GR binding sites in the nucleus. (A) Nuclei prepared from CHO cells transfected with the MMTV promoter construct pHCWT, GR, and/or Oct-2 expression plasmids and treated with 106 M Dex or vehicle for 15 min were restricted with HindIII and digested with  exonuclease (exo) as indicated. Digestion was revealed by linear PCR extension of a primer extending from +74 to +52 of the MMTV LTR, and pause sites were positioned relative to A and T sequencing tracks amplified with the same primer. The Dex-, GR-, and Oct-2-specific  pause site is indicated by the solid arrow, while the constitutive pause site generated by NF1 is indicated by the open arrow. The positions of transcription factor binding sites in the MMTV LTR are indicated schematically to the right of the autoradiogram. (B) Nuclei prepared from CHO cells transfected with pBluescript containing the strong GRE and octamer motif sequences from the MMTV LTR separated by 29 nucleotides (8) and GR and/or Oct-2 expression plasmids and treated with 106 M Dex or vehicle for 15 min were restricted with SmaI and digested with  exonuclease as indicated. Digestion was revealed by linear PCR extension of a T3 polymerase primer, and pause sites were positioned relative to an A sequencing track amplified with the same primer. The positions of the octamer motif sequence and GRE sequences in the MMTV LTR are summarized schematically. The Dex-, GR-, and Oct-2-specific  pause site is indicated by the arrow. (C) Nuclei prepared from CHO cells transfected with pBluescript containing either a Gal4 binding site separated by 8 nucleotides from the octamer motif sequence from the MMTV LTR (left) or a nonspecific oligonucleotide encoding an IAP enhancer core (right) along with Gal-GRWT, Gal-GRL501P, and/or Oct-2 expression plasmids were restricted with XhoI and digested with  exonuclease as indicated. Digestion was revealed by linear PCR extension of a T7 polymerase primer, and pause sites were positioned relative to an A sequencing track amplified with the same primer. The positions of the octamer motif-IAP sequence and of the Gal4 sequence are summarized schematically. The Gal-GRWT-, Oct-2-, and octamer motif-dependent specific  pause site is indicated by the arrow. Western blots of cellular extracts verified that Gal-GRWT and Gal-GRL501P were expressed to the same levels (73).

Recruitment potentiates the activation of transcription by the octamer factors to levels that cannot otherwise be attained in the cell. The ability of many transcription factors, including Oct-1/2, to activate transcription is usually directly proportional to their affinities for individual response elements and to their concentrations in the nucleus. Thus, when joined to minimal promoters, weak octamer factor binding sites direct the activation of transcription by Oct-1/2 more poorly than high-affinity binding sites (19). When considered in this context, the dramatic L501P-sensitive increase of Oct-2 DNA binding we observed with GR might be expected to dramatically potentiate the activation of transcription by Oct-2 from promoters with octamer motifs and GR binding sites linked in cis. Further, this effect might be expected to account for a significant proportion of the transcriptional cooperativity observed between GR and Oct-1/2 on such promoters (8, 101).

View larger version (26K): [in this window] [in a new window]   FIG. 7.   Gal-GRWT dramatically potentiates octamer motif-dependent activation of transcription by Oct-2 and Oct-1-VP16. The interaction of full-length Oct-2 (shaded bars) and Oct-1-VP16 (hatched bars) with Gal-GR fusion proteins was examined with reporter plasmids containing five Gal4 binding sites 5' to four mutated (A) or WT (B) octamer motifs upstream of a minimal E1B promoter and CAT gene. The Gal4 DBD alone (GalO) or Gal-GR fusion proteins were coexpressed with Oct-2 (shaded bars) or Oct-1-VP16 (hatched bars). The black bars show activity in the absence of ectopically expressed proteins (lanes 1). Expression of GalO alone had no significant effect on CAT activity generated from the octamer mutant reporter construct (52).

View larger version (17K): [in this window] [in a new window]   FIG. 8.   GR binding potentiates the activation of transcription by Oct-2 far above the level that can be obtained by ectopic expression of Oct-2 alone. CAT activity from the E1B reporter with five Gal4 binding sites and four octamer motifs was determined upon cotransfection of increasing amounts of Oct-2 expression plasmid in the presence of a fixed amount of a Gal-GRWT (circles) or Gal-GRL501P (squares) expression vector. The results with Gal-GRL501P are shown on an enlarged scale in the inset. CAT activity from experiments with increasing amounts of Oct-2 transfected alone or in the presence of GalO reached a plateau of activation (~5 relative CAT units) by 400 ng of Oct-2, with a slow decline thereafter to background levels (~0.3 relative CAT units) (data not shown). The data represent the means and standard errors of the means of results from three to five independent experiments.

Binding of GR to a GRE destabilizes association with Oct-1/2. Despite the strength of the two-hybrid effect we observed with the GR DBD tethered to DNA through the Gal4 DBD, previous authors have demonstrated that Oct-1 and Oct-2 do not appear to enhance the activation of transcription through a GRE in the absence of octamer motifs (101). Similarly, we observed that expression of Oct-2 had no effect on the ability of the Gal-GR fusion protein to activate transcription from a GRE (52). These results suggested the intriguing possibility that the binding of GR to DNA might be exclusive of the continued interaction with Oct-1/2 that we have observed in solution.

View larger version (51K): [in this window] [in a new window]   FIG. 9.   The binding of GR to Oct-1 POU in solution is sensitive to the presence of a GRE. (A) Following the incubation of GR with GST-Oct-1 POU, binding was challenged with a consensus GRE (lane 2), highly sheared CT DNA (lane 3), or nonspecific oligonucleotides encoding an IAP enhancer core (lane 4) or a binding site for the Ku autoantigen on the C3H MMTV LTR (lane 5). GST-Oct-1 POU binding was determined by exposure of an SDS-polyacrylamide gel and compared to that of 10% of the in vitro-translated GR added to the incubation. (B) EMSA with nuclear extracts prepared from untransfected CHO cells and cells transfected with expression plasmids for Gal-GRWT, Gal-GRL501P, or Oct-2. The radiolabelled oligonucleotide employed contained a single Gal4 binding site and an octamer motif. Nuclear extracts were preincubated prior to the addition of the labelled probe and competitor DNAs. Incubation was continued for a further 20 min prior to PAGE. The individual combinations of nuclear extracts and unlabelled competitor oligonucleotides (added at a 100-fold molar excess) are summarized at the top of the panel.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

We have examined the ability of GR to bind directly to Oct-1/2 and have investigated the consequences of this protein-protein interaction for DNA binding and transcriptional activation by Oct-1/2. Our results indicate that the binding of the GR DBD to the POU domains of Oct-1 and Oct-2 dramatically potentiates the ability of the octamer factors to activate transcription in a promoter-specific manner by encouraging the occupancy of octamer motifs adjacent to GREs. Interestingly, GR-Oct-1/2 binding appeared to be incompatible with the binding of GR to a GRE. These data suggest a mechanism for transcriptional cooperativity between GR and Oct-1/2 in which protein-protein interactions between GR and the octamer factors occur in a way designed to restrict transcriptional cooperativity to promoters containing DNA binding sites for both factors.

The formation of a complex between the DNA binding domain of GR and the POU domain of Oct-1 was evidenced in several different assays. GST pulldown experiments demonstrated that full-length GR could bind specifically to the POU domains of Oct-1 and Oct-2. Binding was localized to the GR DBD and occurred in a manner that was independent of zinc coordination, as neither point mutation of zinc-coordinating cysteines or treatment of the zinc fingers with H₂O₂ influenced POU domain binding in vitro. However, individual mutation of two amino acids in the DNA-contact helix of finger 2 of the GR DBD (56), C500Y and L501P, did block GR-Oct-1/2 binding in vitro and in two-hybrid assays in mammalian cells. Further, the L501P mutation was sufficient to prevent the binding of full-length GR to full-length Oct-1/2 in immunoprecipitation experiments and abrogated the coordinate binding of GR and Oct-2 to DNA in EMSA.

These results suggest that a surface in the GR DBD that is distinct from, but that overlaps, the DNA binding interface of the DBD, mediates specific binding to Oct-1/2 in the cell. Overlap between the two interfaces appears to be limited, as several point mutations that interfered with GR DNA binding and/or DNA-dependent dimerization (R479K, R489K, and N491S), had no effect on POU domain binding. Further, although the mutations C500Y and L501P interfere with POU domain binding, crystallographic (56) and nuclear magnetic resonance (4) analysis of the GR DBD places these amino acids on the surface of the second DNA-contact -helix of the GR DBD that is oriented inwards, towards the core of the DBD. It therefore seems unlikely that either amino acid directly contacts the POU domain. We suggest that it is more probable that the C500Y and L501P mutations force a change in the tertiary structure of the GR DBD that alters the configuration of the POU binding surface in a way that results in a loss of binding.

Many protein-protein interactions have also been mapped to the POU domains of Oct-1 and -2 and to the homeodomain of other homeobox proteins that affect either DNA binding site selection or the transcriptional response of these factors (18, 32, 98). The two best-characterized interactions with octamer factors are those with VP16 (42, 46) and the coactivator Bob1 (also known as Oca-B and OBF-1) (33, 57, 84), with binding to VP16 being specific to Oct-1. In additional binding studies, we have verified that GR can bind specifically to the homeodomains of Oct-1 and Oct-2 (99a). Further, in our experiments, a point mutation in the homeodomain that has previously been reported to distinguish VP16 binding (46) has no effect on GR binding (data not shown). Therefore, it seems that while the presence of a POU-specific domain increases the specificity and affinity of DNA sequence recognition by POU homeodomain proteins, additional interactions, including that observed here with GR, may still be required to direct and increase the binding of these factors to octamer motifs in the cell.

Truncation of GR from the C terminus indicated that the potential to bind Oct-1/2 was lost upon deletion into the DBD. Perhaps surprisingly, preliminary binding and two-hybrid studies attempting to delimit the N-terminal requirements for the binding of GR to Oct-1/2 suggest that the entire GR DBD may be required (99). Thus, although the zinc-coordinated tertiary structure of the GR zinc fingers was not required for octamer factor binding, other determinants within this region, or the overall folding of the DBD, are likely to prove necessary for Oct-1/2 binding.

It is interesting that the GR DBD can engage in protein-protein interactions with a number of other sequence-specific transcription factors, including AP-1, NF-B, NF-IL6, Stat5, and Nur77 (37, 63, 68, 81, 82, 104). Moreover, these interactions are usually mediated by the DBD of the other factor as well. By contrast, interactions between GR and other factors that do not bind DNA, transcriptional coactivators or heat shock protein 90, for example (14, 38), occur outside the DBD. In vitro DNA binding experiments suggest that DBD-DBD interactions can modify the DNA binding potential of GR and/or its partner. Thus, GR binding to AP-1 modifies the DNA binding potentials of both factors, repressing binding to simple motifs in favor of composite elements (26). Similarly, GR binding to NF-B and Nur77 represses the levels of DNA binding of these factors (37, 68). By contrast, binding to Stat5 represses GR DNA binding (82).

The consequences of the binding of GR to Oct-1/2 appear to be distinct from those of other protein-protein interactions with the GR DBD described to date. Unlike Stat5, AP-1, NF-B, and Nur77 binding, association with Oct-1/2 is not expected to impair or modify GR DNA binding. Furthermore, the C500Y and L501P mutations that we have identified have not been reported to disrupt the binding of GR to the other factors. However, as no direct comparison has been made, a more detailed analysis of GR-Oct-1/2 binding requirements will be needed to clarify the distinction between this interaction and other protein binding events mediated by the GR DBD.

In vitro footprinting of the DNA binding of GR and Oct-1/2 indicated that GR binding to the MMTV LTR decreased the concentration of Oct-1 required to saturate the MMTV octamer motifs (8). Our results indicate that GR has a similar ability to promote the binding of Oct-1/2 to the MMTV octamer motifs on plasmid DNA in the cell. They also indicate that this recruitment of Oct-1/2 to the MMTV LTR is dependent upon L501P-sensitive GR-Oct-1/2 binding. Exonuclease footprinting of specific nuclear factor binding to a DNA template containing a single GRE and an MMTV octamer motif showed that Oct-2-dependent occupancy of the octamer motifs was strongly induced by liganded GR and did not involve any additional sequence-specific or general transcription factors. The same potentiation of binding was observed when the GR DBD was tethered to DNA by a Gal4 DNA binding site adjacent to the octamer motif. Further, in this instance, binding to the octamer motif was completely sensitive to the L501P mutation in the GR DBD, which abrogated GR-Oct-1/2 binding in other assays. The implication of these results is that the steroid-dependent occupancy of octamer motifs in the MMTV LTR observed in vivo on chromatin is likely to depend to a large extent on the association of GR and Oct-1/2. This possibility is in direct contrast to NF1 binding to the MMTV LTR, which appears to be entirely dependent on the remodelling of the chromatin structure (91).

Interestingly, the Oct-2- and GR-dependent pause site that we observed on the MMTV LTR mapped at 49, exactly between the two octamer motifs. An explanation for the location of this pause is not obvious as GR-Oct-2-dependent binding to a subcloned distal octamer motif (61 to 51) was able to impede digestion by the exonuclease. However, this result is exactly consistent with exonuclease pausing previously reported in in vivo footprinting of MMTV LTR chromatin that also placed a steroid-dependent pause site at 49 (21). At the time, this pause was ascribed to basal transcription factor binding to the MMTV TATA box. Our results now suggest that it is more likely that this pause reflects the binding of octamer factors to the MMTV LTR.

While our results agree with almost all of the in vitro and in vivo GR-Oct-1/2 DNA binding data obtained to date, they at first glance appear to conflict with the results of a previous report in which Oct-1 binding to the transiently transfected MMTV LTR was not detected to increase in response to hormone treatment (50). However, in these experiments, exonuclease III was the processive enzyme employed in the footprinting. A subsequent report demonstrated that the 49 pause site, and thus Oct-1/2 binding, can be detected only with  exonuclease (61).

The extent to which the promotion of octamer factor DNA binding by GR affected transcriptional activation by Oct-1/2 was examined in transient transfection assays. The use of truncated GR-Gal4 DBD fusion proteins unable to activate reporter gene expression when they were expressed alone allowed us to directly correlate octamer factor DNA binding with transcriptional activation. With the simple reporter system employed, the L501P-sensitive promotion of octamer factor DNA binding directly correlated with an increase in the transcriptional activation potential of Oct-1/2 of close to 2 orders of magnitude. This transcriptional effect was entirely dependent upon the presence of Gal4 DNA binding sites in the reporter gene promoter. Therefore, we propose that binding to GR provides a strong selective advantage for the activation of transcription by octamer factors from glucocorticoid-responsive promoters. Furthermore, these results suggest one way in which transcriptional activation by a constitutively active nuclear factor can be made dependent on inducible signals.

An unusual feature of the potentiation of Oct-1/2 DNA binding by GR was that the GR-Oct-1/2 association in solution was at least significantly weakened by the binding of GR to a GRE. In both GST pulldown experiments and EMSA, the addition of a GRE but not nonspecific DNAs resulted in the disruption of GR-Oct-1/2 binding. This result has not previously been reported for other instances of cooperative DNA binding of transcription factors. One obvious potential advantage to weakening the link between GR and Oct-1/2 following the binding of GR to DNA would be a tighter control of gene expression by reducing the potential for Oct-1/2 to influence the transcription of GR-responsive genes lacking octamer motifs. Thus, Oct-1 and Oct-2 are not expected to act as transcriptional coactivators of GR, despite their ability to bind in solution. A potential disadvantage of this effect is predicted to be the inability of GR to recruit Oct-1/2 to octamer motifs following the DNA binding of GR. However, as demonstrated in our experiments and by in vivo footprinting experiments performed with cells expressing normal levels of GR and Oct-1 (91), this limitation does not appear to be a major detriment to recruiting Oct-1/2 to the MMTV promoter.

Two potential ways in which GR-Oct-1/2 binding in solution may lead to the simultaneous binding of GR and Oct-1/2 to promoters are summarized schematically in Fig. 10. In the first instance (Fig. 10A), association of GR and Oct-1/2 DBDs in solution occurs in a manner which leaves the GR DBD free to recognize and initiate binding to GREs (step i). However, binding of GR to the GRE is incompatible with continued association with Oct-1/2 and leads to the release of the octamer factors from GR (step ii). When release occurs within transcriptional regulatory regions containing octamer motifs, Oct-1 and -2 binding is encouraged through an increase in their local concentrations (step iii). In the absence of an octamer motif, however, the octamer factor is not retained. One additional advantage of this mechanism is that it minimizes the requirement for precise juxtaposition of the GREs and octamer motifs. While we have not performed a rigorous evaluation of this possibility, the promotion of Oct-2 binding to transiently transfected plasmid DNAs by GR was not observed to be sensitive to the spacing between, or the orientations of, the GREs and octamer motifs used in this study.

View larger version (21K): [in this window] [in a new window]   FIG. 10.   Two possible mechanisms for the recruitment of Oct-1/2 by GR to octamer motifs adjacent to GREs. (A) Upon treatment with steroid, liganded GR is transported into the nucleus, where it can form a complex with Oct-1/2 through an interface that involves the zinc fingers of GR and the POU domain of Oct-1/2 (step i). Mutations L501P and C500Y in the GR DBD specifically abrogate octamer factor binding. Although the binding to Oct-1/2 requires determinants in the GR DBD, GR complexed with Oct-1/2 retains the ability to recognize and bind to a GRE (step ii). Binding of GR to a GRE is preferred to, and destabilizes, binding to Oct-1/2. During the course of GR DNA binding, the interaction between GR and Oct-1/2 is weakened in a manner that leads to the release of the octamer factor from GR in vitro. In the absence of nearby octamer motifs, the octamer factor is not retained. However, in the presence of an adjacent octamer motif, the release of Oct-1/2 directly promotes octamer motif binding (step iii). (B) The second mechanism is similar to that shown in panel A, except that the associated GR and octamer factors bind coordinately to transcriptional regulatory regions containing GREs and octamer motifs linked in cis. Coordinate binding may potentially occur in preference to binding by the individual factors to regulatory regions with binding sites for only GR or Oct-1/2.

A second possibility is that on transcriptional regulatory regions containing both octamer motifs and GREs, associated GR and Oct-1/2 initiate DNA binding at the same time (Fig. 10B). This joint binding would be a more direct way to facilitate octamer factor binding and is supported by our results demonstrating that Gal-GR fusion proteins also promoted the binding of Oct-2 adjacent to Gal4 binding sites. However, another report that full-length GR represses the ability of Oct-1 to bind to octamer motifs in the absence of GREs (45) suggests that GR may still need to release the octamer factor for DNA binding to occur. Interestingly, in both the previous study and in preliminary experiments that we have performed (73), the GR DBD alone is unable to repress octamer factor DNA binding in vitro or to repress octamer factor-dependent transcription in transfection experiments. Thus, it seems that the repression of octamer factor DNA binding by full-length GR depends on determinants outside the minimal region of GR required for octamer factor binding in solution. Finally, while not indicated in Fig. 10, neither model for recruitment of Oct-1/2 to DNA by GR specifically excludes the possibility of continued, but fundamentally altered, interaction between GR and Oct-1 or Oct-2 when both factors are bound to their respective response elements.

One approach that is expected to provide additional insight into the mechanism through which GR-Oct-1/2 association promotes the binding of Oct-1/2 to DNA would be to examine how complex formation affects the kinetics of Oct-1/2 DNA binding. For example, continued association of GR and Oct-1/2 following DNA binding might be expected to decrease the rate of dissociation of Oct-1/2 from octamer motifs. By contrast, the release of Oct-1/2 into solution adjacent to octamer motifs is expected to increase the on rate for Oct-1/2 DNA binding.

Finally, our results suggest that the recruitment of Oct-1/2 to DNA by GR plays a major role in promoting the occupancy of octamer motifs in the MMTV and other glucocorticoid-responsive promoters in vivo on chromatin templates. However, in order to directly evaluate this prediction, it will be necessary to identify mutations in the GR DBD that block Oct-1/2 binding without affecting the binding of GR to DNA or the ability of GR to promote the rearrangement of chromatin.