Adf-1 Is a Nonmodular Transcription Factor That Contains a TAF-Binding Myb-Like Motif

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Mol Cell Biol, April 1998, p. 2252-2261, Vol. 18, No. 4
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Adf-1 Is a Nonmodular Transcription Factor That Contains a TAF-Binding Myb-Like Motif

Gene Cutler, Kathleen M. Perry, and Robert Tjian^*

Howard Hughes Medical Institute, University of California, Berkeley, California 94720

Received 28 October 1997/Returned for modification 7 January 1998/Accepted 27 January 1998

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

Adf-1 is an essential Drosophila melanogaster sequence-specific transactivator that binds the promoters of a diverse groupof genes. We have performed a comprehensive mapping of the functionaldomains of Adf-1 to study the role of transactivators in the processof gene activation. Using a series of clustered point mutationsand small deletions we have identified regions of Adf-1 requiredfor DNA binding, dimerization, and activation. In contrast tomost enhancer-binding factors, the Adf-1 activation regions arenonmodular and depend on an intact protein, including the Adf-1DNA-binding domain, for activity. Like many transcriptional activators,Adf-1 contains a TFIID-binding domain that can interact with specificTAF subunits. Although TAFs are required for Adf-1-directed activation,TAF binding is not sufficient, suggesting that Adf-1 may directmultiple essential steps during activation. Interestingly, boththe TAF-binding domain and the DNA-binding domain contain sequenceshomologous to those of the Myb family of DNA-binding domains.Thus, Adf-1 has evolved an unusual structure containing two versionsof the Myb motif, one that binds DNA and one that binds proteins.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

A major form of cellular regulation occurs at the level of transcriptional activation. The control of transactivation is,in turn, largely due to the modulation of site-specific transcriptionfactor activities in the nuclei of eukaryotic cells. A significantadvance was the realization that many promoter- and enhancer-specifictranscriptional activators are modular, with separable DNA-bindingand activation domains (15, 25). The modularity of transcriptionfactors has been useful in elucidating the structure and functionof DNA-binding and activation domains. For example, many DNA-bindingdomains (DBDs) have been well characterized and fall within oneof less than a dozen major structural families (e.g., helix-turn-helix,zinc finger, basic helix-loop-helix) (29). In contrast, thecharacterization of the transcription activation domains of theseproteins has proven more challenging.

Numerous mechanisms have been proposed for transcriptional activation including DNA-bending, recruitment of various basaltranscription factors such as TFIID and RNA polymerase, alterationsof chromatin structure, and the targeting of cofactors (16,35). The complexity of most transcription factors suggests thatmultiple mechanisms are likely to be utilized for efficient activationby any given activator and at any given promoter. In the contextof the paradigm of modularity, transactivating regions of proteinshave often been studied by fusing them to heterologous DBDs. Varioustypes of activation domains have been mapped by this approach,revealing, in many cases, protein sequences with a preponderanceof certain residues (e.g., acidic, glutamine, proline) (22,36) but little information concerning three-dimensional structure.Despite these studies, discrete activation domain boundaries haveoften been difficult to define. Rather, increasingly large deletionsincrementally compromise the potency of activation regions (20).Alternatively, the expedient construction of artificial "hybrid"activators has been useful for mapping minimal functional activatorsin many cases. However, the use of heterologous protein fusionseliminates potentially important intramolecular interactions thatmay occur between activation domains and other regions of thenative protein. Likewise, other factors that may play a role inthe potency of these activation domains, such as their naturaloligomerization states and their positioning with respect to DNA,cannot be studied when activation domains are analyzed out oftheir native context. Consequently, our understanding of the mechanismsby which these activation domains function remains superficialor incomplete in most cases.

In an attempt to circumvent some of these inherent difficulties in dissecting the activities of a transcriptional activator,we have chosen to analyze the Drosophila melanogaster transcriptionfactor Adf-1. Although first identified as a factor that boundthe distal promoter of the gene for alcohol dehydrogenase (Adh)(18), Adf-1 recognizes specific sites in a diverse group ofpromoters including antennapedia P1 and dopa decarboxylase (14).Its ubiquitous expression (13) and its requirement for viability(10) establish the important role of Adf-1 in Drosophila biology.The sequence of Adf-1 revealed that its presumptive DBD is a distantlyrelated member of the Myb helix-turn-helix family (13, 24),whereas no significant similarities to the sequences associatedwith any activation domain categories were observed. This suggestedthat Adf-1 may function through a novel type of transactivationdomain. Adf-1 is also one of the smallest eukaryotic transcriptionfactors thus far identified, with a calculated mass of less than30 kDa. Its small size presented an opportunity to define a conciseactivation domain that could be studied in its native context.This, taken together with the essential role that Adf-1 playsin Drosophila and the opportunity to dissect a novel activationdomain, prompted us to undertake a detailed functional analysisof this enhancer-binding protein.

Here, we report a detailed functional mapping of Adf-1. We generated a series of clustered point mutations and small deletionsthroughout the protein to probe functional regions of Adf-1. Thesealterations were relatively small so as to minimize potentialstructural perturbations, although such perturbations can neverbe completely avoided. The mutant proteins were assayed for transactivation,DNA binding, and oligomerization through a variety of assays.By measuring reporter activity in Drosophila cells cotransfectedwith mutant Adf-1 genes as well as by testing purified recombinantproteins by in vitro transcription, we have discovered that Adf-1differs dramatically from typical modular transcription factors.Activation by Adf-1 critically depends on its DBD. The nonmodularactivation regions contain a TFIID interaction domain that bindsspecifically to TAF_II110 and TAF_II250. Although we demonstratethat TAFs are required for Adf-1 activity, they are not sufficient.Our data suggest that regions of Adf-1 besides the TAF-bindingdomain play additional essential roles in transactivation. Interestingly,the Adf-1 dimerization and TAF-binding region also appears tobe a Myb-like domain, suggesting a novel use for the Myb domainin mediating protein-protein interactions rather than bindingDNA. Additionally, this domain has similarity to a putative protein-bindingregion of the transcriptional adapter ADA2, implying that theremay be a wider family of proteins containing Myb-like proteininteraction domains.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Construction of Adf-1 mutants. PCR primers matching the sequences immediately downstream and upstream of an Adf-1 cDNA cloned into pBlueScript KS+ were generated(wt left 5' primer and wt right 3' primer). The wt left 5' primerincluded an EcoRI restriction site, and the wt right 3' primerincluded an XbaI site for later subcloning. At the site of eachof the alanine-scanning mutations, two mutagenizing PCR primerswere generated. The mutagenizing left 3' primer (m left 3' primer)consisted of approximately 12 nucleotides of wild-type sequencefollowed by a sequence coding for five alanines and containinga NotI site, followed by a stop codon and an XbaI site. The mutagenizingright 5' primer (m right 5' primer) contained an EcoRI site followedby a sequence coding for five alanines, with PstI and NotI sites,followed by roughly 12 nucleotides of wild-type sequence. PCRwas performed with Taq polymerase, with the pBlueScript KS+ Adf-1plasmid as the template and either wt left 5' and m left 3' primers(left PCR) or m right 5' and wt right 3' primers (right PCR).The products of each pair of PCRs were digested with EcoRI andXbaI and cloned into pBlueScript KS+. These were sequenced, andthe correct clones were digested with either EcoRI and NotI (leftproduct) or NotI and XbaI (right product). The two DNA fragmentswere ligated together into EcoRI- and XbaI-digested pBlueScriptKS+. Most of the deletions were generated by ligating left andright halves from PCRs for adjoining pairs of mutants. $Delta$ N5, $Delta$ N12,and 5A245 were generated with only one mutagenizing PCR primerand one wild-type PCR primer. Mutant Adf-1 clones were subclonedfrom pBlueScript KS+ and ligated into pPAC Nde for Schneider celltransfections or into pET-3a or pET-21a for Escherichia coli proteinexpression.

Transfections and CAT assays. Transfection of Schneider SL2 cells was done by a CaPO₄ protocol previously described (30). Into each well of a six-wellplate, 2.5 ml of cells at a density of 2.5 × 10⁶ cells per ml was added. These cells were incubated with 0.4 mlof a CaPO₄ mixture including 0.5 µg of reporter plasmid, 1.25µg of expression plasmid, and salmon sperm DNA to a final totalof 5.5 µg of DNA. The reporter plasmid was a G5BCAT construct(23) containing nucleotides $-$ 71 to $-$ 47 of the alcohol dehydrogenasedistal promoter cloned into the SalI site. The expression plasmidwas either pPAC Nde (3) alone or pPAC Nde containing the genefor wild-type or mutant Adf-1 cloned into the NdeI and XbaI sites.

Two days posttransfection, cells were harvested, washed with phosphate-buffered saline, and resuspended in 40 µl of 0.25 MTris (pH 7.9). These samples were subjected to three freeze-thawcycles and spun briefly to eliminate cellular debris. From them20 µl was removed, heated for 5 min at 65°C, and used for chloramphenicolacetyltransferase (CAT) assays as described previously (9).Data from at least two sets of transfections were quantitatedon a Fuji phosphorimager and averaged. The protein concentrationsof the extracts used for CAT assays, measured by a Bradford assay,were used to adjust the CAT assay data. Additionally, 10 µl ofthe frozen and thawed extracts was run on sodium dodecyl sulfate(SDS)-10% polyacrylamide gels, blotted to nitrocellulose, andprobed with anti-Adf-1 polyclonal antibodies to qualitativelymeasure protein levels. For electrophoretic mobility shift assay(EMSA) experiments, 2.5 µl of the frozen and thawed extracts wasused.

Nuclear localization was assayed by using nuclear and cytoplasmic extracts from transfected cells (1) for Western blots,which were probed with anti-Adf-1 antibodies.

Protein expression and purification. Mutant and wild-type genes for Adf-1 cloned into pET-3a (13) or pET-21a were transformed into E. coli BL21 (DE3) containingthe pLysS plasmid. These were grown in Luria broth to an opticaldensity at 600 nm of 0.5 and induced for 1 h with 0.8 mM IPTG(isopropyl- $beta$ -D-thiogalactopyranoside). Cells were lysed with aFrench press in buffer containing 25 mM HEPES (pH 7.6), 0.4 MNaCl, 0.5 mM EDTA, 0.01% Nonidet P-40 (NP-40), 5 mM dithiothreitol(DTT), 5 mM $beta$ -mercaptoethanol, 0.2 mM phenylmethylsulfonyl fluoride,and 1 mM sodium metabisulfate. This extract was centrifuged for1 h at 35,000 rpm in a Ti45 rotor. The supernatant was passedover a 10 ml DEAE-Sepharose column. The flowthrough was dilutedwith an equal volume of 0 M NaCl buffer. This was passed overa 5-ml SP-Sepharose column. The column was washed with 0.2 M NaClbuffer and eluted with 0.5 M NaCl buffer. Fractions containingAdf-1 protein were pooled and diluted with an equal volume of0 M NaCl buffer. This protein was passed over a 0.5-ml DNA affinitycolumn containing streptavidin-Sepharose beads bound to biotinylatedDNA corresponding to nucleotides $-$ 89 to $-$ 47 of the Adh distalpromoter. The column was washed with 0.25 M NaCl buffer and elutedwith 0.5 M NaCl buffer. Adf-1 eluted from the DNA affinity columnwas nearly homogenous as determined by Coomassie staining. Duringstorage, Adf-1 is converted to a slower-electrophoretic-mobilityform. This form of Adf-1 cannot be separated from the primaryform chromatographically and may be the result of a proline isomerization.

EMSAs. For EMSA experiments using Schneider cell extracts, 2.5 µl of transfected cell extract was incubated for 10 min at 20°C ina 16-µl reaction mixture containing approximately 70 fmol of labeledAdf-1 binding site probe, 0.9 µg of salmon sperm DNA as a nonspecificcompetitor (a ratio of approximately 2,000:1 relative to the specificprobe), and 1× EMSA buffer (10 mM Tris [pH 7.9], 4.5% Ficoll 400,4 mM MgCl2, 0.1 mM EDTA, 50 µg of bovine serum albumin per ml,0.2% NP-40, 1 mM DTT). Samples were electrophoresed over a 5%acrylamide gel (0.5× Tris-borate-EDTA (TBE), 0.75 mM EDTA, 0.05%NP-40) in 0.5× TBE buffer at 250 V. The specific probe was preparedby end labeling oligonucleotides corresponding to nucleotides $-$ 71 to $-$ 47 of the alcohol dehydrogenase distal promoter with ³²P. EMSA experiments with purified protein were essentially identicalexcept that 50 mM NaCl was added to the binding-reaction mixtures.

Glutaraldehyde cross-linking. To a 40-µl reaction mixture containing 50 mM HEPES (pH 7.6) and 100 mM NaCl, 80 ng of purified Adf-1 protein was added. Tothis, 1.25 µl of 0.08% glutaraldehyde was added, and the mixturewas incubated at 20°C for 2.5 min. Ten-microliter samples wereremoved and added to 5 µl of SDS-polyacrylamide gel electrophoresis(PAGE) loading dye to quench the reactions. These samples werethen run on SDS-10% acrylamide gels, blotted to nitrocellulose,and probed with anti-Adf-1 antibodies.

Protein-binding assays. Full length TAFs and portions of TAF_II110 and TAF_II250 were transcribed and translated in vitro in 25 µl of rabbit reticulocytelysates from the TNT kit (Promega) containing [³⁵S]methionine programmed with the appropriate pt $beta$ Stop vectors (21).To this, 200 µl of 0.1 M NaCl HEMG buffer (25 mM HEPES [pH 7.6],0.1 mM EDTA, 12.5 mM MgCl, 10% glycerol) containing 0.01% NP-40was added. After 10 min of high-speed centrifugation, 50 µl oflysate was added to 5 µl of the appropriate glutathione beads.The beads had been prepared by incubating them with E. coli extractcontaining either glutathione S-transferase (GST) protein or GSTfused to the carboxy-terminal 92 amino acids of Adf-1 (C92 fragment)and then washing them extensively with 0.5 M NaCl HEMG buffer.After binding for 4 h at 4°C, the beads were washed four timeswith 0.1 M NaCl HEMG containing 0.01% NP-40. Bound protein waseluted by boiling the beads in SDS-PAGE loading buffer and wassubjected to electrophoresis followed by autoradiography.

For binding with full-length wild-type and mutant Adf-1 proteins, 500 ng of E. coli purified Adf-1 proteins was incubatedfor 5 h at 4°C with 2.5 to 5 µl of the appropriate beads, followedby five washes with 0.2 M NaCl HEMG containing 0.1% NP-40. Boundprotein was eluted by boiling the beads in SDS-PAGE loading bufferand then was subjected to electrophoresis, followed by Westernblotting and probing with anti-Adf-1 antibodies. Western blotswere also probed with anti-TAF antibodies to determine that equalamounts of target protein were used. Beads were created by incubatingwhole-cell extracts from Sf9 cells infected with baculovirus containingexpression constructs for HA-TAF_II110, HA-hTAF_II250, or GST-hNTAF_II250(amino acids 1 to 414) or by incubating E. coli extracts containingGST-NTAF_II110 (amino acids 75 to 208) or GST alone with eitheranti-HA-Sepharose (HA monoclonal antibodies covalently linkedto protein A-Sepharose beads) or glutathione-Sepharose beads (Pharmacia),as appropriate. TFIID beads were created by incubating a purifiedDrosophila TFIID fraction (Mono-Q) (17) with protein A-Sepharosebeads (Pharmacia) bound to anti-TAF_II250 monoclonal antibodies.All beads were then washed extensively with 0.5 or 1.0 M NaClHEMG-0.1% NP-40-0.1% CHAPS {3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate}.

The yeast two-hybrid experiments were performed as described previously (19). DNA coding for the carboxy-terminal 92 aminoacids of Adf-1 and for the Sp1 B domain was cloned into the GAL4activation domain containing plasmid pAS1 (11), and DNA codingfor fragments TAFII110 and hTAFII250 was cloned into the GAL4DBD (amino acids 1 to 147) plasmid, pGAD (25). These were cotransformedinto Saccharomyces cerevisiae Y153 containing LacZ under the controlof a GAL4-responsive promoter. After several days of growth onselective media containing X-Gal (5-bromo-4-chloro-3-indolyl- $beta$ -D-galactopyranoside),yeast colonies were scored for the presence or absence of bluecolor. Controls containing either the GAL4 DBD alone cotransformedwith the C92-GAL4 acidic activation domain (AAD) or the GAL4 AADalone cotransformed with each of the TAF-GAL4 DBD fusions scorednegative.

All the TAF sequences used were from Drosophila except for human hTAF_II250 in some cases, as indicated in the figure legends.

In vitro transcription. In vitro transcription and primer extension experiments were performed as described previously (18). Mutant and wild-typeAdf-1 transcription was assayed in 20-µl reaction volumes containing15 ng of activator, 1.5 µl of H.4 Drosophila embryo extract (12,38) (that had been immunodepleted of endogenous Adf-1; see below)40 ng of nucleotide $-$ 86 template (18), 40 ng of nucleotide $-$ 46template (similar to nucleotide $-$ 86 template except for containingnucleotides $-$ 46 to +13 of the alcohol dehydrogenase distal promoterand producing a shorter transcript), 0.5× HEMG buffer, 50 mM KCl,8 U of RNasin, 1 mM DTT, and 0.625 mM ribonucleoside triphosphates.The activator was preincubated with buffer for 15 min at 20°C.To this, depleted H.4 extract was added, and the mixture was incubatedfor an additional 5 min, followed by the addition of nucleotidesand transcription for 10 min at 20°C. In vitro transcription productswere assayed by primer extension (23). H.4 extract was immunodepletedof Adf-1 by incubating the extract with protein A-Sepharose beadsbound to affinity-purified anti-Adf-1 antibodies overnight at4°C.

To determine TFIID requirements, transcription was performed with a mixture containing 10 ng of activator, the H.4 fractionthat had been immunodepleted against Adf-1, TAF_II250, and TATA-bindingprotein (TBP); the mixture was supplemented with 25 ng of E. coli-producedTFIIA, 6 ng of purified Drosophila TFIIE, and 0.84 µl of a DrosophilaS-300 fraction containing TFIIF, TFIIH, and PolII. To this, either1.2 µl of a Drosophila Mono-Q fraction containing TFIID or 5 ngof E. coli-produced TBP was added. The basal transcription factorswere purified as described previously (17). All protein fractionswere preincubated together for 15 min at 20°C, then buffer andnucleotides were added, and the mixture was incubated for 15 minat 20°C to allow transcription to proceed. The reaction mixtureswere reverse transcribed and electrophoresed to assay in vitrotranscription products.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Mutational analysis of Adf-1 maps DNA-binding, dimerization, and activation regions. To probe the functions of various parts of Adf-1, we performed an alanine-scanning mutagenesis analysis by substituting clustersof three to five amino acids at a time. These mutations were spacedapproximately 10 amino acids apart except in the amino-terminal80 amino acids, which has homology to the Myb family of helix-turn-helixDBDs (13). Twelve groups of alanine-scanning mutations directedtowards the carboxy-terminal two-thirds of Adf-1 were sufficientto probe the activities of the protein (Fig. 1). Additionally,small deletions were made by deleting the amino acids betweenadjacent pairs of alanine-scanning mutations. Two small deletionsat the amino terminus and one at the carboxy terminus were alsoconstructed (Fig. 1). The number of alanines and the positionat which they start are indicated in the name of each of the substitutionmutants, and the range of amino acids removed is indicated foreach of the deletions.

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FIG. 1. The mutagenesis of Adf-1 allowed the mapping of DNA-binding and transactivation activities by using Schneider cell transfections. Twenty-six mutant forms of Adf-1 were constructed and assayed following Schneider cell transfections. The amino and carboxy halves of Adf-1 are shown with nonnative amino acids highlighted. Internally deleted amino acids are indicated with dashes. Data obtained from quantitating mobility shift experiments using extracts from Schneider cells transfected with wild-type and mutant expression vectors and Adf-1 binding site probes are summarized in the "DNA binding" column. Data obtained from quantitating CAT assays using extracts of cells cotransfected with Adf-1 expression vectors and an Adf-1-responsive CAT vector are summarized in the "Transactivation" column. Symbols (both columns): +++, activity at least 70% of that of the wild type; ++, activity between 30 and 69% of that of the wild type; +, activity between 10 and 29% of that of the wild type; $-$ , activity less than 10% of that of the wild type. Background activity was standardized to 0% of that of the wild type.

To assay the activities of these proteins, expression vectors containing the wild-type or mutant genes under the control ofa constitutive actin promoter were transfected into DrosophilaSchneider L2 cells. A minimal promoter containing an Adf-1 bindingsite from the alcohol dehydrogenase distal promoter (13, 14,17, 18) (data not shown) and the adenovirus E1B TATA sequencewere used to drive the expression of a CAT reporter gene. Schneidercells constitutively express a low level of Adf-1, so carefultitration of expression vector, reporter vector, and carrier DNAwas performed to minimize the background signal. Following transfection,extracts were made from the Schneider cells and assayed for CATactivity. These cell extracts were also used in EMSAs. A summaryof the data obtained from these DNA-binding and transactivationassays for all the mutants is shown in Fig. 1. Additionally, Westernblots were made with whole-cell and nuclear extracts of transfectedcells and probed with anti-Adf-1 antibodies to confirm that allthe transfected genes were expressed at similar levels and werelocalized in the nucleus (data not shown).

The EMSAs identified two regions in Adf-1 that contribute to DNA binding (Fig. 1). The most dramatic effects on DNA bindingwere seen with four amino-terminal mutants ( $Delta$ N12, $Delta$ 60-78, 5A88,and $Delta$ 88-105) (Fig. 2A). This region contains the Myb motif (13),and a truncated protein containing only the amino-terminal 130amino acids retains sequence-specific DNA-binding activity (datanot shown). These data suggest that this amino-terminal regionis a bona fide DBD. A second group of mutants lying near the carboxyterminus of Adf-1 also compromised DNA binding (Fig. 1). Interestingly,two of these, mutants 5A214 and 5A228, gave rise to Adf-1-DNAcomplexes that migrated aberrantly in EMSA experiments (Fig. 2B,lanes 3 and 4). Mutant 5A214 gave rise to a weak shift with mobilityhigher than that of the other full-length forms of Adf-1. In contrast,the 5A228 protein produced a shifted species that migrated moreslowly than the other complexes. A mobility shift product at theposition of the wild-type protein-DNA complex in each of thesecases is attributed to DNA binding by wild-type endogenous Adf-1(such as in Fig. 2A, lane 1).

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FIG. 2. Mutations in two regions of Adf-1 decrease DNA-binding affinity. (A) Wild-type and amino-terminal mutant forms of Adf-1 were tested for their abilities to bind an Adf-1 binding site in mobility shift experiments. Lane 1, background DNA binding due to endogenous Adf-1 in extracts from cells transfected with a negative-control expression vector; lanes 2 to 12, mobility-shifts for cell extracts transfected with the indicated expression vectors. (B) Wild-type and carboxy-terminal mutant forms of Adf-1 were tested for their abilities to bind an Adf-1 binding site-containing probe. Lanes 1 to 5, mobility shifts obtained with extracts from cells transfected with wild-type and mutant Adf-1 as described for panel A; lanes 6 to 11, mobility shifts obtained with 5 (lanes 6, 8, and 10) and 50 ng (lanes 7, 9, and 11) of purified recombinant wild-type and mutant Adf-1 proteins, respectively; lanes 12 and 13, mobility shifts obtained with 0.5 and 1 µl, respectively, of partially purified recombinant 5A228 protein. The positions of aberrant mobility shifts are indicated by arrowheads. (C) Chemical cross-linking of wild-type and mutant forms of Adf-1. Wild-type and mutant forms of Adf-1 were incubated in the presence or absence of 0.0025% glutaraldehyde and then subjected to SDS-PAGE followed by Western blotting and probing with anti-Adf-1 antibodies. The positions of prestained molecular weight standards and the presumed oligomeric states of the Adf-1 species are indicated. The lower band in the N228 samples (lanes 7 and 8) indicates a degradation product. kD, kilodaltons. (D) Schematic of Adf-1 in which the regions that affect DNA binding and the region of Myb homology are indicated. The amino-terminal region is the bona fide DBD, while the carboxy-terminal region is required for dimerization.

To further characterize the behavior of these mutants, wild-type Adf-1 and several carboxy-terminal mutant proteins were expressedin E. coli and purified to homogeneity for EMSA characterization.Mutant 5A228 protein was expressed very poorly and could not bepurified easily, so this protein was only partially purified fromE. coli extract. In the EMSA, purified mutant 5A214 produced aspecies that migrated similarly to the 5A214-DNA complex producedfrom transfected Schneider cells (Fig. 2B; compare lanes 3, 8,and 9). In addition a less-abundant species that migrated moreslowly than the wild-type Adf-1-DNA complex was observed (Fig.2B, lanes 8 and 9). Recombinant 5A228 protein also produced asimilarly migrating pair of complexes (Fig. 2B, lanes 12 and 13).These observations prompted us to hypothesize that Adf-1 may bindDNA as a dimer and that mutations in the region between aminoacids 200 and 228 may disrupt this dimerization. We predictedthat mutant monomeric forms of Adf-1 bound singly or doubly toa dimer DNA site, producing the two observed shifts. Wild-typeAdf-1, in contrast, would bind exclusively as a dimer, producingonly one species of protein-DNA complex.

To obtain additional evidence for dimer formation by Adf-1, we performed glutaraldehyde cross-linking experiments with purifiedwild-type and mutant Adf-1 proteins (Fig. 2C). In the presenceof 0.0025% glutaraldehyde, wild-type protein is efficiently convertedfrom its monomeric form (migrating at 35 kDa in SDS-PAGE) to acovalently dimerized species (migrating at 70 kDa) (Fig. 2C, lanes1 and 2). Many of the mutant forms of Adf-1, including mutant5A186 (Fig. 2C, lanes 3 and 4) and mutant 5A245 (Fig. 2C, lanes9 and 10), were also efficiently cross-linked by glutaraldehyde.In contrast, mutants 5A214 (Fig. 2C, lanes 5 and 6) and N228 (Fig.2C, lanes 7 and 8) produced virtually no detectable dimer speciesupon glutaraldehyde treatment. Although high concentrations ofthe 5A214 mutant led to a complex in the EMSA with lower mobility,which may be caused by two molecules of 5A214 bound adjacentlyon DNA containing a dimeric Adf-1 binding site (Fig. 2B, lane9), the addition of DNA to the glutaraldehyde cross-linking reactionmixture failed to induce the cross-linking of the 5A214 mutantprotein (data not shown). The results of these chemical cross-linkingexperiments, taken together with the aberrant mobility shift results,suggest that mutant 5A214 is unable to form dimers in solutionand that two monomeric 5A214 molecules, when bound to adjacentsites on DNA, are in a conformation different from that of a wild-typedimer bound to DNA. Mutant 5A228 protein from Drosophila transfectionsforms a low-mobility complex in an EMSA, which cannot be reproducedwith E. coli-produced protein. Mutant 5A228 may only be partiallydefective in dimerization and is perhaps able to interact withendogenous wild-type Adf-1 in an unusual complex leading to itsaberrant migration. Alternatively, it may be forming higher-ordermultimers or fortuitously interacting with other unknown Drosophilaproteins. Mutant 5A200 protein from transfections formed a normallymigrating complex, although to a lesser extent than did the wild-typeprotein (Fig. 2B, lane 2). Unfortunately, we could not test theE. coli-produced 5A200 protein for dimerization because of itstoxicity to E. coli. Thus, our data suggest that wild-type Adf-1contains an amino-terminal DBD and that DNA binding by this domainis enhanced by protein dimerization that requires a region ofAdf-1 between amino acids 200 and 245 (summarized in Fig. 2D).

Transcriptional activation by Adf-1. To probe the activation properties of Adf-1, CAT assays were performed with extracts from Schneider cells transfected withwild-type and mutant Adf-1. Wild-type protein directs activationof the CAT reporter at levels significantly above background,while many of the mutants gave rise to little or no CAT activityabove endogenous background levels (Fig. 3A; summarized in Fig.1). Surprisingly, few alanine-scanning or deletion mutants retainedtranscriptional activity. The only region clearly dispensablefor activation lies between amino acids 102 and 120 (Fig. 1),immediately adjacent to the DBD. This region is followed by ashort glutamine-rich region, although the importance of this regionin activation is not clear from the data. Contrary to expectations,the $Delta$ 158-176 and $Delta$ 186-204 deletion mutants are more transcriptionallyactive than the alanine-scanning mutants which they incorporate,and the reasons for this are not clear. Interestingly, removalof just the amino-terminal five amino acids ( $Delta$ N5) produced a proteinthat can bind DNA but that has very little transcriptional activity(Fig. 1). These results provide the first evidence that transactivationby Adf-1 may require an integrated rather than a modular activationdomain.

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FIG. 3. Regions of Adf-1 that are required for transcriptional activation. (A) Extracts from transfected cells were used for CAT assays to measure the transcriptional activities of wild-type and mutant forms of Adf-1. Lane 1, background CAT activity from extracts of cells transfected with a negative-control expression vector; lanes 2 to 6, results of CAT assays using extracts of cells transfected with Adf-1 expression vectors. Converted and unconverted forms of [¹⁴C]chloramphenicol are indicated. (B) Purified wild-type and mutant forms of Adf-1 behave similarly in in vitro and in vivo transcription. Lane 1, in vitro transcription signal from a reaction mixture containing a partially purified Drosophila embryo extract; the Adh distal position $-$ 86 template contains Adf-1 binding sites, while the Adh distal position $-$ 46 template does not; lanes 2 to 6, the same transcription system as in lane 1 with 15 ng of purified wild-type or mutant Adf-1 added. (C) A schematic of Adf-1 in which the regions that affect activation are indicated. The DBD is partially filled since it is not possible to discriminate between direct and indirect effects on activation by mutations in this region.

To further characterize the transcriptional activation properties of wild-type and mutant forms of Adf-1, several of theseproteins were tested in an in vitro transcription system composedof partially purified Drosophila embryo extracts that had beenimmunodepleted of endogenous Adf-1. A template containing thealcohol dehydrogenase distal promoter extending to position $-$ 86(containing the natural Adf-1 binding sites) (18) and a controltemplate containing a truncated enhancer extending to position $-$ 46 (lacking the Adf-1 binding sites and giving rise to a shortertranscript) were added to our transcription system along withpurified recombinant wild-type or mutant forms of Adf-1. The additionof wild-type Adf-1 produced a high level of transcriptional activationon the template containing the Adf-1 binding site (Fig. 3B, lane2). The addition of no activator or the Adf-1 minimal DBD alone(N130) produced no significant activation (lanes 1 and 3). Twoother mutants, 3A131 and 5A186, that displayed little transcriptionalactivity in vivo were also largely inactive in this in vitro transcriptionsystem (lanes 4 and 5). Conversely, an alanine variant that isactive in vivo, 5A245, is also fully active in vitro (lane 6).A slight activation of the negative-control template with activeproteins (lanes 2 and 6) and a slight inhibition with inactiveproteins (lanes 3 to 5) can be seen, presumably due to low levelsof Adf-1 binding to cryptic binding sites and dominant-negativeeffects of the inactive mutants.

The mapping of sequences required for transactivation is summarized in Fig. 3C. Interestingly, no region of Adf-1 is competentfor transactivation when separated from its natural DBD domainand fused to the heterologous DBDs of GAL4 or Sp1 (data not shown).These results, taken together, strongly suggest that competencyfor activation by Adf-1 requires a structure that includes anintact DBD; this structure deviates substantially from the typicalmodular construction of most other enhancer-binding proteins.

Adf-1 binds TAFs to activate transcription. Many transcriptional activators have been shown to interact with the TAF subunits of the TFIID complex, and this interactionhas been correlated with transactivation in several cases (6,7, 31, 33, 34). We next tested whether TAFs were importantin Adf-1-directed transcription and, if so, whether there wasany correlation between activation and potential Adf-1-TAF interactions.Our Adf-1-dependent in vitro transcription system was depletedof TFIID by using antibodies against both TAF_II250 and TBP. Inthe absence of an exogenous source of TFIID, this transcriptionsystem was inactive (data not shown). The addition of either purifiedTFIID or purified recombinant TBP to the depleted transcriptionsystem restored basal transcription levels (Fig. 4A, lanes 1 and3; the slight activation seen in lane 1 is due to residual endogenousAdf-1). The addition of purified Adf-1 to these reaction mixturesled to a high level of activation when TFIID was present but hadno effect on the reaction mixture containing only TBP (Fig. 4A,lanes 2 and 4). These results suggest that Adf-1, like many Drosophilaactivators, requires the presence of TAFs in order to activatetranscription in vitro.

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FIG. 4. Activation by Adf-1 requires the presence of TAFs, and Adf-1 is able to interact directly with the TFIID complex. (A) The TFIID complex is required by Adf-1 to activate transcription. The transcription system used for Fig. 3B was depleted of TFIID activity. Purified TFIID (lanes 1 and 2) or purified recombinant TBP (lanes 3 and 4) was added back either in the absence of added activator (lanes 1 and 3) or with 10 ng of purified wild-type Adf-1 (lanes 2 and 4). (B) Adf-1 can interact directly with purified TFIID, while some mutants cannot. Purified TFIID was immunoprecipitated with beads containing anti-TAF_II250 antibodies. These beads (lanes 4 to 6) or negative-control GST beads (lanes 7 to 9) were incubated with wild-type or mutant forms of Adf-1, washed extensively, and subjected to SDS-PAGE followed by Western blotting and probing with anti-Adf-1 ( $alpha$ -Adf-1) antibodies. Results for 5% of the input wild-type and mutant Adf-1 are also shown (lanes 1 to 3). The upper bands seen in lanes 1 and 4 are believed to result from an isomeric form of Adf-1 (see Materials and Methods). The lower band seen in lane 2 results from a degradation product.

To determine if the transcriptional requirement for TAFs was due to direct interactions between one or more of these proteinsand Adf-1, in vitro binding experiments were conducted. Beadscontaining anti-TAF_II250 monoclonal antibodies were used to immunoprecipitateTFIID from partially purified TFIID fractions. Silver stainingand Western blotting using anti-TAF_II80 antibodies confirmed thatan intact holo-TFIID complex was immunoprecipitated (data notshown). Purified wild-type or mutant Adf-1 protein was incubatedwith these TFIID beads or with negative-control beads. Anti-Adf-1antibodies were used to visualize the amounts of bound and inputAdf-1 proteins on Western blots (Fig. 4B). We could not detectany of the Adf-1 proteins binding to the negative-control beads(lanes 7 to 9), whereas wild-type Adf-1 bound strongly to beadscontaining TFIID (lane 4). In contrast, the two carboxy-terminaltranscriptionally inactive mutants, 5A214 and N228, failed tobind the TFIID beads (lanes 5 and 6), suggesting that the carboxyterminus of Adf-1 is necessary for TFIID binding.

The Drosophila TFIID complex includes TBP and approximately eight major TAFs (37). To determine which of these were boundby Adf-1, each of the eight TAFs and TBP were produced by in vitrotranscription and translation in the presence of ³⁵S-labeled methionine. The lysates were then incubated with glutathionebeads bound to either GST fused to the carboxy terminus of Adf-1(C92; amino acids 162 to 253) or to GST alone. The C92 fragmentwas used since the TFIID-binding data suggested that TAF-bindingactivity may reside in the carboxy terminus of Adf-1. After extensivewashing, bound and input TAFs were visualized by autoradiography.Of the nine proteins, only TAF_II110 and TAF_II250 bound at significantlevels to Adf-1 (Fig. 5A and data not shown). The similar amountsof TAF binding observed with full-length Adf-1 and with proteinshaving amino-terminal deletions of Adf-1 further confirm thatthe carboxy terminus of Adf-1 is the major TAF-binding determinantin the protein (Fig. 5A; compare lanes 3 to 5). Smaller fragmentsof TAF_II110 and hTAF_II250 were also tested for their ability tobind Adf-1 (Fig. 5B). We found that the carboxy-terminal 240 aminoacids of TAF_II110 were sufficient for binding Adf-1, while bindingwith regions at both the amino and carboxy termini of hTAF_II250was seen. The central portion of hTAF_II250 also bound Adf-1, thoughto a lesser extent. This binding also demonstrated that the carboxy-terminalregion of Adf-1 is sufficient for TAF binding.

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FIG. 5. Regions of TAF_II110 and TAF_II250 bind the carboxy terminus of Adf-1. (A) The carboxy terminus of Adf-1 binds TAF_II110 and TAF_II250. TAF_II110 and TAF_II250 ( $Delta$ N660) were incubated with glutathione beads bound to GST alone (lanes 2 and 8), GST-Adf-1 amino acids 162 to 253 (C92) (lanes 3 and 9), GST-Adf-1 amino acids 92 to 253 (C162) (lane 4), or GST-Adf-1 full length (wt) (lane 5). Bound TAFs were visualized by autoradiography of SDS-PAGE gels after extensive washing. in (lanes 1 and 7), 10% lysate input; $-$ , binding to negative-control beads. The positions of the TAF products are indicated by open circles. (B) One region of TAF_II110 and multiple regions of TAF_II250 are responsible for Adf-1 binding. Full-length and truncated forms of TAF_II110, TAF_II250, and hTAF_II250 were incubated with glutathione beads bound to GST-Adf-1 C92 or to GST alone and visualized by autoradiography after extensive washing. +, binding to GST-Adf-1 C92; in and $-$ are as defined for panel A. The positions of TAF products are indicated by open circles. (C) Adf-1 binds the same regions of TAF_II110 and TAF_II250 in vivo as it does in vitro. A C92 fragment of Adf-1 fused to the GAL4 AAD and portions of TAF_II110 and TAF_II250 fused to the GAL4 DBD or the DBD alone (as indicated) were coexpressed in S. cerevisiae containing a GAL4-responsive LacZ gene. Schematics of TAF_II110 and hTAF_II250 are shown with shading indicating the relative amounts of binding to Adf-1 in vitro, as shown in panel B. Below these are bars representing the portions of TAF_II110 and hTAF_II250 fused to the DBD. The amounts of LacZ activity seen are summarized in the "Lac-Z" column; the symbols represent the relative level of LacZ signal observed. (D) Some of the Adf-1 mutants are defective for TAF binding. Purified Adf-1 proteins were incubated with beads bound to hTAF_II250 (lanes 4 to 6), TAF_II110 (lanes 7 to 9), NTAF_II110 (amino acids 75 to 208) (lanes 10 to 12), NTAF_II250 (amino acids 1 to 414) (lanes 15 to 18), and GST (lanes 19 to 22). The beads were washed extensively and subjected to SDS-PAGE, followed by Western blotting and probing with anti-Adf-1 antibodies. Lanes 1 to 3 and 11 to 14 show results for 10% input wild-type and mutant Adf-1 proteins. The upper bands seen in some of the lanes represent isomeric forms of Adf-1 (see Materials and Methods), and the lower bands in the N228 samples (lanes 2 and 12) represent degradation products. (E) Schematic of Adf-1, with the region required for binding to TAF_II110 and TAF_II250 indicated.

To verify that the in vitro binding we observed reflected events that can occur inside of a cell, we also tested the interactionbetween Adf-1 and TAF_II110 and hTAF_II250 in S. cerevisiae. Severalportions of both TAFs were fused to the GAL4 DBD, and the carboxyterminus of Adf-1 was fused to the GAL4 AAD. These vectors werecotransformed into S. cerevisiae containing GAL4 sites upstreamof the gene for $beta$ -galactosidase. As summarized in Fig. 5C, theregions of TAF_II110 and hTAF_II250 that bound Adf-1 in vitro alsointeracted efficiently in this "in vivo" two-hybrid assay.

Several of the mutations in the carboxy-terminal region of Adf-1 decreased its ability to activate transcription. As was shownin Fig. 4B, some of these carboxy-terminal Adf-1 mutants are alsodeficient for binding to the holo-TFIID complex. Similar experimentsusing individual TAFs and other Adf-1 mutants were performed toexamine these results in more detail. Paralleling the TFIID-bindingresults, mutants 5A214 and N228 bound with low efficiency to full-lengthhTAF_II250 and TAF_II110 as well as to an amino-terminal fragmentof hTAF_II250 (amino acids 1 to 414) (Fig. 5D, lanes 5 to 9 and15 to 17). As expected, none of these proteins bound to GST aloneor to GST fused to the amino terminus of TAF_II110 (amino acids75 to 208) (Fig. 5D, lanes 10 to 12 and 19 to 21). In contrast,another carboxy-terminal mutant, 5A245, that is fully active fortransactivation retains the ability to bind hTAF_II250 efficiently(Fig. 5D, lane 18). Mutants 3A131 and 5A186, bearing alterationsin the central portion of Adf-1, also bound TAFs at levels similarto that of the wild-type protein (data not shown). These resultsprovide a good correlation between TAF binding and transcriptionalactivation by the carboxy-terminal region of Adf-1. However, becauseactivation by Adf-1 requires sequences outside of the carboxy-terminalregion, we suspect that binding may be necessary but not sufficientto stimulate transcriptional activation by Adf-1. Instead, ourresults suggest that sequences outside of the TAF interactionregion contribute additional activities essential for transactivation.

The carboxy-terminal TAF-binding domain of Adf-1 bears homologies to ADA2 and Myb. A BLAST search for sequences similar to that of the TAF-binding domain of Adf-1 revealed a sequence similarity with a regionof the S. cerevisiae transcriptional adapter protein ADA2 (Fig.6A). In fact, the number of residues at the carboxy terminus ofAdf-1 (AdfC) that are identical or homologous to those of theyeast ADA2 is almost as high as that between the human and yeastADA2 proteins over this region. The region of highest homologyis in the region between amino acids 223 and 247 of Adf-1. Thecorresponding region of ADA2 has been shown to be essential forits biological function and is required for binding another transcriptionaladapter protein, GCN5 (4). Examination of the sequence of Adf-1by eye also suggested that this same region has homology withthe Adf-1 amino-terminal Myb domain (AdfN). Interestingly, ithas been reported that the corresponding region of ADA2 also containsa Myb domain homology (2, 5). ADA2 is more similar to Adf-1than to Myb (52% similarity between Adf-1 and yADA2 versus 43%similarity between mouse Myb repeat 2 and yADA2) (Fig. 6B), suggestingthat Adf-1 and ADA2 may contain domains belonging to a novel subfamilyof Myb sequences.

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FIG. 6. The carboxy terminus of Adf-1 is homologous to ADA2 and to Myb DBDs. (A) The carboxy terminus of Adf-1 is homologous to a region of the S. cerevisiae and human ADA2 proteins. An alignment between amino acids 182 and 247 of Adf-1 (Adf C), amino acids 65 and 110 of yeast ADA2 (yADA2), and amino acids 75 and 120 of human ADA2 (hADA2) is shown. The position of a 15-residue insertion in Adf-1 is indicated. All residues that are highly similar or identical to those of yADA2 are indicated by shading. The percent similarities between all sequences and that of yADA2 are indicated. Similar amino acids are PG, ST, DE, NQ, RHK, AVLIM, and FTW. (B) The carboxy terminus of Adf-1 may be a Myb-like domain. AdfC and yADA2 are aligned to two DNA-binding Myb domains, the amino terminus of Adf-1 (AdfN; amino acids 6 to 69) and M. musculus Myb repeat 2 (Myb2; amino acids 95 to 141). Amino acid positions in AdfC are indicated, as are the positions of sequence insertions in AdfC and AdfN. Residues that are identical or highly similar to those of Myb2 are indicated as in panel A. Percent similarities between all sequences and that of Myb2 are indicated. The positions of helices 1, 2, and 3 in Myb2 are indicated by brackets. Seven residues whose side chains project from the exposed face of mMyb helix 3 are indicated by asterisks.

Unlike the AdfC and ADA2 sequences, previously characterized Myb domains have only been shown to bind DNA. The high-resolutionstructures of several Myb domains have been solved (26, 28),revealing that they are variants of the helix-turn-helix motif.An alignment of AdfC to yADA2 and two DNA-binding Myb domains,AdfN and the second Myb repeat of the mouse Myb protein, is shownin Fig. 6B. The level of similarity between AdfC and Myb is similarto that between Myb and the two other sequences which are alreadyrecognized as being Myb homologs, AdfN and yADA2 (Fig. 6B) (2,5, 13, 24). Interestingly, the region of greatest similaritybetween AdfC and yADA2 is also the region of least similaritybetween those two proteins and Myb and AdfN. This region correspondsto Myb helix 3, the DNA-recognition helix of DNA-binding Myb domains.The mouse Myb structure reveals that seven residues (Fig. 6B)in helix 3, including those that specifically recognize DNA (26-28),project out from the protein. While all seven of these residuesare hydrophilic in the mouse Myb sequence and six are hydrophilicin the Adf-1 DBD, only three are hydrophilic in the Adf-1 carboxy-terminalregion. Thus, this region of Adf-1, which may correspond to theDNA-recognition surface of typical Myb domains, may be much morehydrophobic than that of any of the DBDs. Fewer hydrophobic substitutionsare seen in this region with ADA2, but there are several largehydrophobic residues in both ADA2 and AdfC immediately carboxyterminal to the helix 3 region that may further contribute toa potential helical hydrophobic surface. This structural arrangementof the Adf-1 carboxy-terminal Myb-like domain is consistent witha role for this domain in protein-protein rather than protein-DNAinteractions.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

Our understanding of the mechanisms of transcriptional activation and the structure of activation domains remains rudimentary.Most characterized enhancer-binding proteins have revealed modularactivation domains that can function when fused to heterologousDBDs. Many activators contain multiple activation regions, butstudying these functional domains in isolation as chimeric fusionsfails to provide us with information about how they may interactwith each other and with their natural DBDs to influence activation.Additionally, structural studies of these activation domains havethus far been difficult and not highly informative. Here we reporta detailed analysis of the Drosophila activator Adf-1. We haveprobed the activities of sequences throughout the protein throughalanine-scanning and deletion mutagenesis. These small modificationsof Adf-1 have allowed us to study the functional domains of Adf-1in their native context, revealing an unusual activation regionand a novel dual use of the Myb motif.

A distinct DBD is located in the amino-terminal 100 amino acids of Adf-1. This domain contains homologies to the Myb DNA-bindingmotif and Drosophila protein Stonewall (8). Adf-1 dimerizesin solution through a domain found near the carboxy terminus.Although dimerization increases the affinity of Adf-1 for DNA,its activity is not essential for binding, as mutants unable todimerize retain sequence-specific DNA-binding activity. Sincemost Myb proteins contain two or three tandem repeats of the Mybmotif, it is possible that the dimerization by Adf-1 compensatesfor the presence of only one DNA-binding Myb motif in the protein.Although monomeric forms of Adf-1 can still bind DNA, they doso with a lower affinity. In addition to being required for dimerization,the carboxy terminus of Adf-1 possesses TAF-binding activity.We show here that TFIID cannot be replaced by TBP for Adf-1-directedtranscriptional activation, consistent with the notion that TAFbinding is likely to be functionally important for the activityof Adf-1. All mutations which disrupt Adf-1 dimerization alsodisrupt TAF binding, while mutants of Adf-1 that are competentfor dimerization are also competent for TAF binding. While thesedata suggest that dimerization may be required for TAF binding,our observation that a carboxy-terminal fragment of Adf-1 containingthe dimerization domain is sufficient for TAF binding indicatesthat dimerization and TAF binding activities are likely due toclosely adjacent or overlapping sequences within Adf-1.

Mutations in both regions of Adf-1, DNA-binding and dimerization/TAF-binding regions, affect transcriptional activation. Surprisingly,several other mutations that do not interfere with these activitiesalso disrupt activation by Adf-1. For example, a deletion of thefirst five residues of the protein ( $Delta$ N5) severely impairs activationby Adf-1. Since DNA binding is an obvious requirement for activationand since the fusions of fragments of Adf-1 with heterologousDBDs which have been tested (data not shown) have proven to beinactive, we cannot conclusively say whether the Adf-1 DBD hasactivities directly required for activation. The transcriptionalphenotype of the $Delta$ N5 protein and the lack of activity of heterologousfusions, however, suggest that a direct role of the Adf-1 DBDin activation is likely. It is not uncommon for amino and carboxytermini to be near each other in the three-dimensional structuresof proteins. One possibility is that there are important interactionsbetween the amino terminus of Adf-1 containing the DBD and thecarboxy-terminal domain where TAF-binding activity resides. Althoughthese interactions are not required for TAF binding in solution,they may help to position the TAF-binding domain with respectto the rest of the protein and to the DNA such that these TAFinteractions are competent for the stimulation of an active transcriptioncomplex. Alternatively, it is possible that the pathway of activationdirected by Adf-1 requires at least one step in addition to TAFbinding and that these other regions of Adf-1 are required forsuch a step.

The functional mapping of Adf-1 is summarized in Fig. 7A. Indicated within the protein are regions predicted to be $alpha$ -helicalby the nearest-neighbor secondary structure prediction algorithm(32). Additionally, the positions of the three Myb domain-likehelices predicted by the alignments of the amino and carboxy terminiof Adf-1 to Myb domains are indicated. Circular dichroism spectroscopyof purified Adf-1 indicates a very high $alpha$ -helical content (datanot shown), supporting these sequence-based predictions. The helicalpredictions based on the primary structure match closely thosebased on the Myb homologies with one major exception. The predictedrecognition helix of the DBD, helix 3, is nearly 50 amino acidslong and terminates near the border of the DBD as defined by ourmutagenesis. This helix is 40 amino acids longer than the correspondinghelices seen in the NMR structures of Myb (26, 28). The closematch with the mapped border of the DBD and the amphiphilic natureof this entire region (data not shown) support the model of agreatly extended DNA recognition helix. A linear extension ofthe recognition helix would, by necessity, project out of themajor groove and lose contact with DNA. If contact between suchan extended recognition helix and DNA is maintained, dramaticperturbations in the helix or in the DNA must exist. Alternatively,the extended recognition helix may be playing an indirect rolein DNA binding.

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FIG. 7. A synthesis of structural and functional information about Adf-1. (A) Secondary structure prediction of Adf-1 correlates with mutagenesis data and protein homologies. $alpha$ -Helices predicted by the nearest-neighbor secondary-structure prediction algorithm are indicated by shading. The positions of helices 1, 2, and 3 predicted by an analysis of the two Myb domain homologies (Fig. 6B) are indicated below the protein. Regions required for DNA binding, activation, TAF binding, and dimerization are indicated above the protein. (B) A model for the structure of Adf-1. The data summarized in panel A are interpreted as a possible three-dimensional structure showing the activities of Adf-1. A dimer of two Adf-1 molecules is depicted bound to DNA. A monomer of Adf-1 contains a DNA-binding helix-turn-helix domain at its amino terminus. The recognition helix that is expected to lie in the major groove of the DNA is shown as an extended helix. The relationship between this helix and DNA is unknown, and the helical kink depicted is arbitrary. The positions and orientations on DNA of the two monomers with respect to each other are also arbitrary. The activities and structures in the central portion of Adf-1 are not well understood, although the region is predicted to contain several $alpha$ -helices. The carboxy terminus of Adf-1 also contains a Myb-like helix-turn-helix domain; this domain is able to dimerize as well as bind TAF_II110 and TAF_II250. Potential interactions are indicated by arrows.

The agreement of the nearest-neighbor analysis results and the positions of the Myb homology-predicted $alpha$ -helices at the carboxyterminus of Adf-1 support the model that a second Myb-like domainexists in the protein. Unlike the case for previously characterizedMyb domains, there is no evidence for direct interactions betweenthis carboxy-terminal domain and DNA. Rather, this region containsdimerization and TAF-binding activities. The known structuresof Myb domains reveal two important protein surfaces, one consistingof helices 1 and 2 and the other containing helix 3, the recognitionhelix. Mutations that disrupt any of these helices or the linkersequence between them, are likely to have effects on the entirestructure. Thus, although both dimerization and TAF-binding activitiesmap to the same general region, it is quite possible that thesetwo activities reside on opposing surfaces of a Myb-like structure.This region in Adf-1 is also similar to that of the transcriptionaladapter protein ADA2. The greatest similarity between Adf-1 andADA2 is in the regions corresponding to the Myb DNA recognitionhelix, which, for these two domains, contains several large hydrophobicresidues. This is consistent with a role for this domain in protein-proteinrather than protein-DNA interactions. A deletion in ADA2 whichremoves the sequence corresponding to Myb helices 2 and 3 eliminatesbinding to another adapter protein, GCN5 (4). Thus, there isa strong likelihood that both Adf-1 and ADA2 contain a novel variantof the Myb domain adapted for protein-protein interactions ratherthan protein-DNA recognition.

A model of Adf-1 based on the data we have presented is shown in Fig. 7B. Some of the features, such as the kink in the extendedrecognition helix and the orientation of the DBDs on DNA, are,by necessity, arbitrary. While the existence of two Myb domainsin a protein is not unprecedented, the very different roles theyplay were unanticipated. The likely use of a Myb domain in protein-proteininteractions by both Adf-1 and ADA2 suggests that a family ofsuch proteins may exist. Another unexpected feature of Adf-1 wasthe nonmodularity of its transcriptional activation region. Adf-1may be much more structurally integrated than previously characterizedtranscription factors. Our observation that TAF binding, whilerequired, is not sufficient for activation suggests that Adf-1may direct multiple steps in the pathway of activation. The typicalcut-and-splice characterization of transcriptional activatorsis likely to obscure such multiple contributions by a protein.In the case of Adf-1, we have a good model for elucidating a morecomplete pathway by which an individual activator functions inthe process of transcriptional activation.

	ACKNOWLEDGMENTS

We thank the members of the Tjian lab, past and present, for their support of this research. We are especially grateful toP. Beaurang, S. Hansen, T. O'Brien, F. Sauer, K. Yokomori, S.Ryu, D. Azivonis, J. Zwicker, and M. Holmes for donations of criticalDNA and protein reagents. We appreciate C. Day and T. Alber fortheir efforts with Adf-1. We additionally thank M. Rabenstein,C. Smith, L. Gandhi, L. de la Fuente, and S. Treisenberg for criticalcomments on the manuscript.

G.C. was supported by a Howard Hughes Predoctoral Fellowship. This work was supported in part by grant no. CA25417 from theNational Institutes of Health to R.T.

	FOOTNOTES

^* Corresponding author. Mailing address: Molecular and Cell Biology, 401 Barker Hall Mailroom, University of California, Berkeley,CA 94720-3204. Phone: (510) 642-0884. Fax: (510) 643-9547. E-mail:jmlim{at}uclink4.berkeley.edu.

Present address: Tulerik Inc., South San Francisco, Calif.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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19. Hoey, T., R. O. Weinzierl, G. Gill, J. L. Chen, B. D. Dynlacht, and R. Tjian. 1993. Molecular cloning and functional analysis of Drosophila TAF110 reveal properties expected of coactivators. Cell 72:247-260[Medline].

20. Hope, I. A., S. Mahadevan, and K. Struhl. 1988. Structural and functional characterization of the short acidic transcriptional activation region of yeast GCN4 protein. Nature 333:635-640[Medline].

21. Jantzen, H. M., A. M. Chow, D. S. King, and R. Tjian. 1992. Multiple domains of the RNA polymerase I activator hUBF interact with the TATA-binding protein complex hSL1 to mediate transcription. Genes Dev. 6:1950-1963[Abstract/Free Full Text].

22. Johnson, P. F., E. Sterneck, and S. C. Williams. 1993. Activation domains of transcriptional regulatory proteins. J. Nutr. Biochem. 4:386-398.

23. Lillie, J. W., and M. R. Green. 1989. Transcription activation by the adenovirus E1a protein. Nature 338:39-44[Medline].

24. Lipsick, J. S. 1996. One billion years of Myb. Oncogene 13:223-235[Medline].

25. Ma, J., and M. Ptashne. 1987. A new class of yeast transcriptional activators. Cell 51:113-119[Medline].

26. Morikawa, S., K. Ogata, A. Sekikawa, A. Sarai, S. Ishii, Y. Nishimura, and H. Nakamura. 1995. Determination of the NMR solution structure of a specific DNA complex of the Myb DNA-binding domain. J. Biomol. NMR 6:294-305[Medline].

27. Ogata, K., S. Morikawa, H. Nakamura, H. Hojo, S. Yoshimura, R. Zhang, S. Aimoto, Y. Ametani, Z. Hirata, A. Sarai, et al. 1995. Comparison of the free and DNA-complexed forms of the DNA-binding domain from c-Myb. Nat. Struct. Biol. 2:309-320[Medline].

28. Ogata, K., S. Morikawa, H. Nakamura, A. Sekikawa, T. Inoue, H. Kanai, A. Sarai, S. Ishii, and Y. Nishimura. 1994. Solution structure of a specific DNA complex of the Myb DNA-binding domain with cooperative recognition helices. Cell 79:639-648[Medline].

29. Pabo, C. O., and R. T. Sauer. 1992. Transcription factors: structural families and principles of DNA recognition. Annu. Rev. Biochem. 61:1053-1095[Medline].

30. Pascal, E., and R. Tjian. 1991. Different activation domains of Sp1 govern formation of multimers and mediate transcriptional synergism. Genes Dev. 5:1646-1656[Abstract/Free Full Text].

31. Petty, K. J., Y. I. Krimkevich, and D. Thomas. 1996. A TATA binding protein-associated factor functions as a coactivator for thyroid hormone receptors. Mol. Endocrinol. 10:1632-1645[Abstract/Free Full Text].

32. Salamov, A. A., and V. V. Solovyev. 1995. Prediction of protein secondary structure by combining nearest-neighbor algorithms and multiple sequence alignments. J. Mol. Biol. 247:11-15[Medline].

33. Sauer, F., D. A. Wassarman, G. M. Rubin, and R. Tjian. 1996. TAF(II)s mediate activation of transcription in the Drosophila embryo. Cell 87:1271-1284[Medline].

34. Thut, C. J., J. L. Chen, R. Klemm, and R. Tjian. 1995. p53 transcriptional activation mediated by coactivators TAFII40 and TAFII60. Science 267:100-104[Abstract/Free Full Text].

35. Tjian, R., and T. Maniatis. 1994. Transcriptional activation: a complex puzzle with few easy pieces. Cell 77:5-8[Medline].

36. Triezenberg, S. J. 1995. Structure and function of transcriptional activation domains. Curr. Opin. Genet. Dev. 5:190-196[Medline].

37. Verrijzer, C. P., and R. Tjian. 1996. TAFs mediate transcriptional activation and promoter selectivity. Trends Biochem. Sci. 21:338-342[Medline].

38. Wampler, S. L., C. M. Tyree, and J. T. Kadonaga. 1990. Fractionation of the general RNA polymerase II transcription factors from Drosophila embryos. J. Biol. Chem. 265:21223-21231[Abstract/Free Full Text].

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1.	Attardi, L. D., and R. Tjian. 1993. Drosophila tissue-specific transcription factor NTF-1 contains a novel isoleucine-rich activation motif. Genes Dev. 7:1341-1353[Abstract/Free Full Text].
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12.	Dynlacht, B. D., T. Hoey, and R. Tjian. 1991. Isolation of coactivators associated with the TATA-binding protein that mediate transcriptional activation. Cell 66:563-576[Medline].
13.	England, B. P., A. Admon, and R. Tjian. 1992. Cloning of Drosophila transcription factor Adf-1 reveals homology to Myb oncoproteins. Proc. Natl. Acad. Sci. USA 89:683-687[Abstract/Free Full Text].
14.	England, B. P., U. Heberlein, and R. Tjian. 1990. Purified Drosophila transcription factor, Adh distal factor-1 (Adf-1), binds to sites in several Drosophila promoters and activates transcription. J. Biol. Chem. 265:5086-5094[Abstract/Free Full Text].
15.	Frankel, A. D., and P. S. Kim. 1991. Modular structure of transcription factors: implications for gene regulation. Cell 65:717-719[Medline].
16.	Goodrich, J. A., G. Cutler, and R. Tjian. 1996. Contacts in context: promoter specificity and macromolecular interactions in transcription. Cell 84:825-830[Medline].
17.	Hansen, S. K., and R. Tjian. 1995. TAFs and TFIIA mediate differential utilization of the tandem Adh promoters. Cell 82:565-575[Medline].
18.	Heberlein, U., B. England, and R. Tjian. 1985. Characterization of Drosophila transcription factors that activate the tandem promoters of the alcohol dehydrogenase gene. Cell 41:965-977[Medline].
19.	Hoey, T., R. O. Weinzierl, G. Gill, J. L. Chen, B. D. Dynlacht, and R. Tjian. 1993. Molecular cloning and functional analysis of Drosophila TAF110 reveal properties expected of coactivators. Cell 72:247-260[Medline].
20.	Hope, I. A., S. Mahadevan, and K. Struhl. 1988. Structural and functional characterization of the short acidic transcriptional activation region of yeast GCN4 protein. Nature 333:635-640[Medline].
21.	Jantzen, H. M., A. M. Chow, D. S. King, and R. Tjian. 1992. Multiple domains of the RNA polymerase I activator hUBF interact with the TATA-binding protein complex hSL1 to mediate transcription. Genes Dev. 6:1950-1963[Abstract/Free Full Text].
22.	Johnson, P. F., E. Sterneck, and S. C. Williams. 1993. Activation domains of transcriptional regulatory proteins. J. Nutr. Biochem. 4:386-398.
23.	Lillie, J. W., and M. R. Green. 1989. Transcription activation by the adenovirus E1a protein. Nature 338:39-44[Medline].
24.	Lipsick, J. S. 1996. One billion years of Myb. Oncogene 13:223-235[Medline].
25.	Ma, J., and M. Ptashne. 1987. A new class of yeast transcriptional activators. Cell 51:113-119[Medline].
26.	Morikawa, S., K. Ogata, A. Sekikawa, A. Sarai, S. Ishii, Y. Nishimura, and H. Nakamura. 1995. Determination of the NMR solution structure of a specific DNA complex of the Myb DNA-binding domain. J. Biomol. NMR 6:294-305[Medline].
27.	Ogata, K., S. Morikawa, H. Nakamura, H. Hojo, S. Yoshimura, R. Zhang, S. Aimoto, Y. Ametani, Z. Hirata, A. Sarai, et al. 1995. Comparison of the free and DNA-complexed forms of the DNA-binding domain from c-Myb. Nat. Struct. Biol. 2:309-320[Medline].
28.	Ogata, K., S. Morikawa, H. Nakamura, A. Sekikawa, T. Inoue, H. Kanai, A. Sarai, S. Ishii, and Y. Nishimura. 1994. Solution structure of a specific DNA complex of the Myb DNA-binding domain with cooperative recognition helices. Cell 79:639-648[Medline].
29.	Pabo, C. O., and R. T. Sauer. 1992. Transcription factors: structural families and principles of DNA recognition. Annu. Rev. Biochem. 61:1053-1095[Medline].
30.	Pascal, E., and R. Tjian. 1991. Different activation domains of Sp1 govern formation of multimers and mediate transcriptional synergism. Genes Dev. 5:1646-1656[Abstract/Free Full Text].
31.	Petty, K. J., Y. I. Krimkevich, and D. Thomas. 1996. A TATA binding protein-associated factor functions as a coactivator for thyroid hormone receptors. Mol. Endocrinol. 10:1632-1645[Abstract/Free Full Text].
32.	Salamov, A. A., and V. V. Solovyev. 1995. Prediction of protein secondary structure by combining nearest-neighbor algorithms and multiple sequence alignments. J. Mol. Biol. 247:11-15[Medline].
33.	Sauer, F., D. A. Wassarman, G. M. Rubin, and R. Tjian. 1996. TAF(II)s mediate activation of transcription in the Drosophila embryo. Cell 87:1271-1284[Medline].
34.	Thut, C. J., J. L. Chen, R. Klemm, and R. Tjian. 1995. p53 transcriptional activation mediated by coactivators TAFII40 and TAFII60. Science 267:100-104[Abstract/Free Full Text].
35.	Tjian, R., and T. Maniatis. 1994. Transcriptional activation: a complex puzzle with few easy pieces. Cell 77:5-8[Medline].
36.	Triezenberg, S. J. 1995. Structure and function of transcriptional activation domains. Curr. Opin. Genet. Dev. 5:190-196[Medline].
37.	Verrijzer, C. P., and R. Tjian. 1996. TAFs mediate transcriptional activation and promoter selectivity. Trends Biochem. Sci. 21:338-342[Medline].
38.	Wampler, S. L., C. M. Tyree, and J. T. Kadonaga. 1990. Fractionation of the general RNA polymerase II transcription factors from Drosophila embryos. J. Biol. Chem. 265:21223-21231[Abstract/Free Full Text].