A bipartite DNA binding domain composed of direct repeats in the TATA box binding factor TFIID

Global analysis of functional relationships between histone point mutations and the effects of histone deacetylase inhibitors

Comprehensive analyses of the histone-GLibrary in previous studies showed that most mutants of modification sites in the histone core regions show phenotypes, whereas those with modifications in the histone N-terminal unstructured tail regions (N-tails) do not. One possible reason is that modifications in N-tails are linked to each other to form a scale-free network termed histone 'modification web'. In the network, the compensatory pathways are created to acquire the robustness against the any defects. Because of this robustness, it is difficult to determine the significance of the individual histone modifications in N-tails in vivo. To overcome this problem, we used a strategy using drugs coordinately to inhibit modification enzymes and observed the mutant phenotypes when the compensatory pathways are largely interrupted. We analyzed histone-GLibrary using inhibitors of histone deacetylases (HDACs) and identified novel phenotypic mutants. We also examined the phenotypic changes through the combined use of an HDAC inhibitor and an inhibitor of DNA-mediated reactions. Mutation of modifiable sites H3-K4 and H4-K16 in histone N-tails, which are presumed to be the 'hubs' of the network, resulted in identifiable phenotypes. The data obtained provide valuable information for speculation on novel relationships between histone modification in N-tails and biological function and for predicting unknown modification sites in core histones.

Global analysis of mutual interaction surfaces of nucleosomes with comprehensive point mutants

The surfaces of core histones in nucleosome are exposed as required for factor recognition, or buried for histone-DNA and histone-histone interactions. To understand the mechanisms by which nucleosome structure and function are coordinately altered in DNA-mediated reactions, it is essential to define the roles of both exposed and buried residues and their functional relationships. For this purpose, we developed GLASP (GLobal Analysis of Surfaces by Point mutation) and GLAMP (GLobal Analysis of Mutual interaction surfaces of multi-subunit protein complex by Point mutation) strategies, both of which are comprehensive analyses by point mutagenesis of exposed and buried residues in nucleosome, respectively. Four distinct DNA-mediated reactions evaluated by Ty suppression (the Spt(-) phenotype), and sensitivities to 6-azauracil (6AU), hydroxyurea (HU), and methyl methanesulfonate (MMS), require common and different GLAMP residues. Mutated GLAMP residues at the interface between histones H2A and H2B mainly affect the Spt(-) phenotype but not HU and MMS sensitivities. Interestingly, among the mutated GLAMP residues surrounding the histone H3-H3' interface, some equally affect the Spt(-) phenotype, and HU and MMS sensitivities, whereas others differentially affect the Spt(-) phenotype, and HU and MMS sensitivities. Based on these and other results, the functional relationships among chromatin factors and GLASP and GLAMP residues provide insights into nucleosome disassembly/assembly processes in DNA-mediated reactions.

Computer-based screening of functional conformers of proteins

A long-standing goal in biology is to establish the link between function, structure, and dynamics of proteins. Considering that protein function at the molecular level is understood by the ability of proteins to bind to other molecules, the limited structural data of proteins in association with other bio-molecules represents a major hurdle to understanding protein function at the structural level. Recent reports show that protein function can be linked to protein structure and dynamics through network centrality analysis, suggesting that the structures of proteins bound to natural ligands may be inferred computationally. In the present work, a new method is described to discriminate protein conformations relevant to the specific recognition of a ligand. The method relies on a scoring system that matches critical residues with central residues in different structures of a given protein. Central residues are the most traversed residues with the same frequency in networks derived from protein structures. We tested our method in a set of 24 different proteins and more than 260,000 structures of these in the absence of a ligand or bound to it. To illustrate the usefulness of our method in the study of the structure/dynamics/function relationship of proteins, we analyzed mutants of the yeast TATA-binding protein with impaired DNA binding. Our results indicate that critical residues for an interaction are preferentially found as central residues of protein structures in complex with a ligand. Thus, our scoring system effectively distinguishes protein conformations relevant to the function of interest.

Proteins participate in most of the doings of the cells through a variety of interactions. There is an intimate relationship between the function of a protein and its three-dimensional structure, but understanding this relationship remains an unsolved problem, in part due to the limited information on protein structures bound to other biological molecules. On the other hand, thousands of protein structures in the unbound or free form, are made public every year and these differ from those of the bound structures. How to predict the protein structure in the bound form may assist researchers in understanding the structure/function relationship. Here we report that protein structures bound to other molecules tend to present, as central amino acids, those that are critical for binding other molecules. This feature allowed us to identify the protein structures known to be involved in protein interactions from a screening of thousands of structures derived from the free form.

Polyglutamine expansion reduces the association of TATA-binding protein with DNA and induces DNA binding-independent neurotoxicity

TATA-binding protein (TBP) is essential for eukaryotic gene transcription. Human TBP contains a polymorphic polyglutamine (polyQ) domain in its N terminus and a DNA-binding domain in its highly conserved C terminus. Expansion of the polyQ domain to >42 glutamines typically results in spinocerebellar ataxia type 17 (SCA17), a neurodegenerative disorder that resembles Huntington disease. Our recent studies have demonstrated that polyQ expansion causes abnormal interaction of TBP with the general transcription factor TFIIB and induces neurodegeneration in transgenic SCA17 mice (Friedman, M. J., Shah, A. G., Fang, Z. H., Ward, E. G., Warren, S. T., Li, S., and Li, X. J. (2007) Nat. Neurosci. 10, 1519-1528). However, it remains unknown how polyQ expansion influences DNA binding by TBP. Here we report that polyQ expansion reduces in vitro binding of TBP to DNA and that mutant TBP fragments lacking an intact C-terminal DNA-binding domain are present in transgenic SCA17 mouse brains. polyQ-expanded TBP with a deletion spanning part of the DNA-binding domain does not bind DNA in vitro but forms nuclear aggregates and inhibits TATA-dependent transcription activity in cultured cells. When this TBP double mutant is expressed in transgenic mice, it forms nuclear inclusions in neurons and causes early death. These findings suggest that the polyQ tract affects the binding of TBP to promoter DNA and that polyQ-expanded TBP can induce neuronal toxicity independent of its interaction with DNA.

Global analysis of functional surfaces of core histones with comprehensive point mutants

The core histones are essential components of the nucleosome that act as global negative regulators of DNA-mediated reactions including transcription, DNA replication and DNA repair. Modified residues in the N-terminal tails are well characterized in transcription, but not in DNA replication and DNA repair. In addition, roles of residues in the core globular domains are not yet well characterized in any DNA-mediated reactions. To comprehensively understand the functional surface(s) of a core histone, we constructed 320 yeast mutant strains, each of which has a point mutation in a core histone, and identified 42 residues responsible for the suppressor of Ty (Spt(-)) phenotypes, and 8, 30 and 61 residues for sensitivities to 6-azauracil (6AU), hydroxyurea (HU) and methyl-methanesulfonate (MMS), respectively. In addition to residues that affect one specific assay, residues involved in multiple reactions were found, and surprisingly, about half of them were clustered at either the nucleosome entry site, the surface required for nucleosome-nucleosome interactions in crystal packing or their surroundings. This comprehensive mutation approach was proved to be powerful for identification of the functional surfaces of a core histone in a variety of DNA-mediated reactions and could be an effective strategy for characterizing other evolutionarily conserved hub-like factors for which surface structural information is available.

The Saccharomyces cerevisiae RNA polymerase III recruitment factor subunits Brf1 and Bdp1 impose a strict sequence preference for the downstream half of the TATA box

Association of the TATA-binding protein (TBP) with its cognate site within eukaryotic promoters is key to accurate and efficient transcriptional initiation. To achieve recruitment of Saccharomyces cerevisiae RNA polymerase III, TBP is associated with two additional factors, Brf1 and Bdp1, to form the initiation factor TFIIIB. Previous data have suggested that the structure or dynamics of the TBP–DNA complex may be altered upon entry of Brf1 and Bdp1 into the complex. We show here, using the altered specificity TBP mutant TBPm3 and an iterative in vitro selection assay, that entry of Brf1 and Bdp1 into the complex imposes a strict sequence preference for the downstream half of the TATA box. Notably, the selected sequence (TGTAAATA) is a perfect match to the TATA box of the RNA polymerase III-transcribed U6 small nuclear RNA (SNR6) gene. We suggest that the selected T•A base pair step at the downstream end of the 8 bp TBP site may provide a DNA flexure that promotes TFIIIB-DNA complex formation.

The yeast FACT complex has a role in transcriptional initiation

A crucial step in eukaryotic transcriptional initiation is recognition of the promoter TATA by the TATA-binding protein (TBP), which then allows TFIIA and TFIIB to be recruited. However, nucleosomes block the interaction between TBP and DNA. We show that the yeast FACT complex (yFACT) promotes TBP binding to a TATA box in chromatin both in vivo and in vitro. The SPT16 gene encodes a subunit of yFACT, and we show that certain spt16 mutations are synthetically lethal with TBP mutants. Some of these genetic defects can be suppressed by TFIIA overexpression, strongly suggesting a role for yFACT in TBP-TFIIA complex formation in vivo. Mutations in the TOA2 subunit of TFIIA that disrupt TBP-TFIIA complex formation in vitro are also synthetically lethal with spt16. In some cases this spt16 toa2 lethality is suppressed by overexpression of TBP or the Nhp6 architectural transcription factor that is also a component of yFACT. The Spt3 protein in the SAGA complex has been shown to regulate TBP binding at certain promoters, and we show that some spt16 phenotypes can be suppressed by spt3 mutations. Chromatin immunoprecipitations show TBP binding to promoters is reduced in single spt16 and spt3 mutants but increases in the spt16 spt3 double mutant, reflecting the mutual suppression seen in the genetic assays. Finally, in vitro studies show that yFACT promotes TBP binding to a TATA sequence within a reconstituted nucleosome in a TFIIA-dependent manner. Thus, yFACT functions in establishing transcription initiation complexes in addition to the previously described role in elongation.

Structural and functional analysis of mutations along the crystallographic dimer interface of the yeast TATA binding protein

The TATA binding protein (TBP) is a central component of the eukaryotic transcription machinery and is subjected to both positive and negative regulation. As is evident from structural and functional studies, TBP's concave DNA binding surface is inhibited by a number of potential mechanisms, including homodimerization and binding to the TAND domain of the TFIID subunit TAF1 (yTAF(II)145/130). Here we further characterized these interactions by creating mutations at 24 amino acids within the Saccharomyces cerevisiae TBP crystallographic dimer interface. These mutants are impaired for dimerization, TAF1 TAND binding, and TATA binding to an extent that is consistent with the crystal or nuclear magnetic resonance structure of these or related interactions. In vivo, these mutants displayed a variety of phenotypes, the severity of which correlated with relative dimer instability in vitro. The phenotypes included a low steady-state level of the mutant TBP, transcriptional derepression, dominant slow growth (partial toxicity), and synthetic toxicity in combination with a deletion of the TAF1 TAND domain. These phenotypes cannot be accounted for by defective interactions with other known TBP inhibitors and likely reflect defects in TBP dimerization.

SPN1, a conserved gene identified by suppression of a postrecruitment-defective yeast TATA-binding protein mutant

Little is known about TATA-binding protein (TBP) functions after recruitment to the TATA element, although several TBP mutants display postrecruitment defects. Here we describe a genetic screen for suppressors of a postrecruitment-defective TBP allele. Suppression was achieved by a single point mutation in a previously uncharacterized Saccharomyces cerevisiae gene, SPN1 (suppresses postrecruitment functions gene number 1). SPN1 is an essential yeast gene that is highly conserved throughout evolution. The suppressing mutation in SPN1 substitutes an asparagine for an invariant lysine at position 192 (spn1(K192N)). The spn1(K192N) strain is able to suppress additional alleles of TBP that possess postrecruitment defects, but not a TBP allele that is postrecruitment competent. In addition, Spn1p does not stably associate with TFIID in vivo. Cells containing the spn1(K192N) allele exhibit a temperature-sensitive phenotype and some defects in activated transcription, whereas constitutive transcription appears relatively robust in the mutant background. Consistent with an important role in postrecruitment functions, transcription from the CYC1 promoter, which has been shown to be regulated by postrecruitment mechanisms, is enhanced in spn1(K192N) cells. Moreover, we find that SPN1 is a member of the SPT gene family, further supporting a functional requirement for the SPN1 gene product in transcriptional processes.

A TRF1:BRF complex directs Drosophila RNA polymerase III transcription

It has been generally accepted that the TATA binding protein (TBP) is a universal mediator of transcription by RNA polymerase I, II, and III. Here we report that the TBP-related factor TRF1 rather than TBP is responsible for RNA polymerase III transcription in Drosophila. Immunoprecipitation and in vitro transcription assays using immunodepleted extracts supplemented with recombinant proteins reveals that a TRF1:BRF complex is required to reconstitute transcription of tRNA, 5S and U6 RNA genes. In vivo, the majority of TRF1 is complexed with BRF and these two proteins colocalize at many polytene chromosome sites containing RNA pol III genes. These data suggest that in Drosophila, TRF1 rather than TBP forms a complex with BRF that plays a major role in RNA pol III transcription.

Binding mechanisms of TATA box-binding proteins: DNA kinking is stabilized by specific hydrogen bonds

One of the common mechanisms of DNA bending by minor groove-binding proteins is the insertion of protein side chains between basepair steps, exemplified in TBP (TATA box-binding protein)/DNA complexes. At the central basepair step of the TATA box TBP produces a noticeable decrease in twist and an increase in roll, while engaging in hydrogen bonds with the bases and sugars. This suggests a mechanism for the stabilization of DNA kinks that was explored here with ab initio quantum mechanical calculations and molecular dynamics/potential of mean force calculations. The hydrogen bonds are found to contribute the energy necessary to drive the conformational transition at the central basepair step. The Asn, Thr, and Gly residues involved in hydrogen bonding to the DNA bases and sugar oxygens form a relatively rigid motif in TBP. The interaction of this motif with DNA is found to be responsible for inducing the untwisting and rolling of the central basepair step. Notably, direct readout is shown not to be capable of discriminating between AA and AT steps, as the strength of the hydrogen bonds between TBP and the DNA are the same for both sequences. Rather, the calculated free energy cost for an equivalent conformational transition is found to be sequence-dependent, and is calculated to be higher for AA steps than for AT steps.

Analysis of the chicken TBP-like protein(tlp) gene: evidence for a striking conservation of vertebrate TLPs and for a close relationship between vertebrate tbp and tlp genes

TLP (TBP-like protein), which is a new protein dis-covered by us, has a structure similar to that of the C-terminal conserved domain (CCD) of TBP, although its function has not yet been elucidated. We isolated cDNA and genomic DNA that encode chicken TLP (cTLP) and determined their structures. The predicted amino acid sequence of cTLP was 98 and 91% identical to that of its mammalian and Xenopus counterparts, respectively, and its translation product was ubiquitously observed in chicken tissues. FISH detection showed that chicken tlp and tbp genes were mapped at 3q2.6-2.8 and 3q2.4-2.6 of the same chromosome, respectively. Genome analysis revealed that the chicken tlp gene was spliced with five introns. Interestingly, the vertebrate tbp genes were also found to be split by five introns when we focused on the CCDs, and their splicing points were similar to those of tlp. On the contrary, another TBP-resembling gene of Drosophila, trf1, is split by only one intron, as is the Drosophila 's tbp gene. These results support our earlier assumption that vertebrate TLPs did not directly descend from Drosophila TRF1. On the basis of these results together with phylogenetical exam-ination, we speculate that tlp diverged from an ancestral tbp gene through a process of gene duplication and point mutations.

Isolation of cDNA, chromosome mapping, and expression of the human TBP-like protein

TBP is an essential factor for eukaryotic transcription. In this study, we identified a human cDNA encoding 21-kDa TBP-like protein (TLP). The TLP ORF, carrying 186 amino acids, covered the entire 180 amino acids of the C-terminal conserved domain of human TBP with 39% identity and 76% similarity. FISH determined that human tlp gene was located at chromosome 6 region q22.1-22.3. Northern blot analysis demonstrated that TLP mRNAs were expressed in various human tissues ubiquitously. We found that the TLP proteins exist in multiple mammalian cells and chicken cells. Although the Drosophila TBP-related factor (TRF) is a neurogenesis-related transcription factor, expression of TLP was nearly constant throughout the neural differentiation of P19 cells. Unlike TRF, TLP did not bind to the TATA-box nor direct transcription initiation in vitro. Similarity between TRF and TLP was considerably lower (35 in alignment score) than that between Drosophila TBP and human TBP (88 in alignment score). Multiple amino acids critical for the TBP function were deleted or substituted in TLP. We suggest that TLP is not a bona fide vertebrate counterpart nor a direct descendant of TRF.

Identification of a mouse TBP-like protein (TLP) distantly related to the drosophila TBP-related factor

TATA-binding protein (TBP) is an essential factor for eukaryotic transcription. In this study, we demonstrated a mouse cDNA encoding a 21 kDa TBP-like protein (TLP). The TLP ORF, carrying 186 amino acids, covered the entire 180 amino acids of the C-terminal conserved domain of mouse TBP with 39% identity and 76% similarity. Northern blot analysis demonstrated that TLP mRNAs were expressed in various mammalian tissues ubiquitously and that their distribution pattern was analogous to that of TBP. By using anti-TLP antibody, we demonstrated the existence of TLP proteins in various mammalian cells and tissues. The Drosophila TBP-related factor (TRF) is a neurogenesis-related transcription factor that binds to the TATA-box and activates transcription. TLP did not bind to the TATA-box nor direct transcription initiation. Multiple amino acids critical for TBP function were deleted or substituted in TLP, while amino acids in Drosophila TRF much resembled those in TBP. Similarity between Drosophila TRF and mouse TLP was considerably lower (alignment score 35) than that between Drosophila TBP and mouse TBP (alignment score 88). Identity of nucleotide sequences between mouse and putative human TLPs (94%) was higher than that between TBPs (91%) in these two animals. Expression of TLP was nearly constant throughout the P19 differentiation process. Accordingly, we suggest that, even if higher eukaryotes generally contain multiple tbp -related genes, TLP is not a bona fide mammalian counterpart of Drosophila TRF.

Architecture of protein and DNA contacts within the TFIIIB-DNA complex

The RNA polymerase III factor TFIIIB forms a stable complex with DNA and can promote multiple rounds of initiation by polymerase. TFIIIB is composed of three subunits, the TATA binding protein (TBP), TFIIB-related factor (BRF), and B". Chemical footprinting, as well as mutagenesis of TBP, BRF, and promoter DNA, was used to probe the architecture of TFIIIB subunits bound to DNA. BRF bound to TBP-DNA through the nonconserved C-terminal region and required 15 bp downstream of the TATA box and as little as 1 bp upstream of the TATA box for stable complex formation. In contrast, formation of complete TFIIIB complexes required 15 bp both upstream and downstream of the TATA box. Hydroxyl radical footprinting of TFIIIB complexes and modeling the results to the TBP-DNA structure suggest that BRF and B" surround TBP on both faces of the TBP-DNA complex and provide an explanation for the exceptional stability of this complex. Competition for binding to TBP by BRF and either TFIIB or TFIIA suggests that BRF binds on the opposite face of the TBP-DNA complex from TFIIB and that the binding sites for TFIIA and BRF overlap. The positions of TBP mutations which are defective in binding BRF suggest that BRF binds to the top and N-terminal leg of TBP. One mutation on the N-terminal leg of TBP specifically affects the binding of the B" subunit.

Minor groove-binding architectural proteins: structure, function, and DNA recognition

To date, high-resolution structures have been solved for five different architectural proteins complexed to their DNA target sites. These include TATA-box-binding protein, integration host factor (IHF), high mobility group I(Y)[HMG I(Y)], and the HMG-box-containing proteins SRY and LEF-1. Each of these proteins interacts with DNA exclusively through minor groove contacts and alters DNA conformation. This paper reviews the structural features of these complexes and the roles they play in facilitating assembly of higher-order protein-DNA complexes and discusses elements that contribute to sequence-specific recognition and conformational changes.

Identification of RTF1, a novel gene important for TATA site selection by TATA box-binding protein in Saccharomyces cerevisiae

Interaction of the TATA box-binding protein (TBP) with promoters of RNA polymerase II-transcribed genes is an early and essential step in mRNA synthesis. Previous studies have demonstrated that the rate-limiting binding of TBP to a TATA element can be influenced by transcriptional regulatory proteins. To identify additional factors that may regulate DNA binding by TBP in vivo, we performed a genetic selection for extragenic suppressors of a yeast TBP mutant that exhibits altered and relaxed DNA binding specificity. This analysis has led to the discovery of a previously unidentified gene, RTF1. The original rtf1 suppressor mutation, which encodes a single amino acid change in Rtf1, and an rtf1 null allele suppress the effects of the TBP specificity mutant by altering transcription initiation. Differences in the patterns of transcription initiation in these strains strongly suggest that the rtf1 missense mutation is distinct from a simple loss-of-function allele. The results of genetic crosses indicate that suppression of TBP mutants by mutations in RTF1 occurs in an allele-specific fashion. In a strain containing wild-type TBP, the rtf1 null mutation suppresses the transcriptional effects of a Ty delta insertion mutation in the promoter of the HIS4 gene, a phenotype also conferred by the TBP altered-specificity mutant. Finally, as shown by indirect immunofluorescence experiments, Rtf1 is a nuclear protein. Taken together, our findings suggest that Rtf1 either directly or indirectly regulates the DNA binding properties of TBP and, consequently, the relative activities of different TATA elements in vivo.

Restoration of TATA-dependent transcription in a heat-inactivated extract of tobacco nuclei by recombinant TATA-binding protein (TBP) from tobacco

We isolated a complementary DNA (cDNA) that encoded a TATA-binding protein (TBP) from a cDNA library of tobacco (Nicotiana tabacum) suspension-cultured cells (BY-2). A comparison among deduced amino acid sequences of plant TBPs revealed the presence of a long conserved region within the amino acid sequence of the TBP. Genomic Southern analysis revealed that tobacco TBP (tTBP) is encoded by only a small number of copies of a gene in the tobacco genome. Addition of recombinant tTBP to an extract of tobacco nuclei (TNE) enhanced the basal transcriptional activity in vitro. This result indicates that the level of tTBP is a rate-limiting factor for basal transcriptional activity in TNE. We subsequently succeeded in the functional complementation of TATA-dependent initiation of transcription that was associated with a plant promoter in a homologous plant system. Addition of bacterially expressed recombinant tTBP to a heat-inactivated TNE restored transcriptional activity, as did the addition of human TBP. Moreover, heating of the recombinant tTBP eliminated its ability to restore transcriptional activity. It appears that the heat inactivation of TNE was caused by the heat inactivation of tTBP in TNE.

A yeast TATA-binding protein mutant that selectively enhances gene expression from weak RNA polymerase II promoters

We describe a unique gain-of-function mutant of the TATA-binding protein (TBP) subunit of Saccharomyces cerevisiae TFIID that, at least in part, renders transcriptional transactivators dispensable for efficient mRNA expression. The yTBPN69S mutant enhances transcription from weaker yeast promoter elements by up to 50-fold yet does not significantly increase gene expression directed by highly active promoters. Therefore, this TBP mutant and transcriptional transactivators appear to affect a common rate-limiting step in transcription initiation. Consistent with the hypothesis that this step is TFIID recruitment, tethering of TBP to a target promoter via a heterologous DNA binding domain, which is known to bypass the need for transcriptional transactivators, also nullifies the enhancing effect exerted by the N69S mutation. These data provide genetic support for the hypothesis that TFIID recruitment represents a rate-limiting step in the initiation of mRNA transcription that is specifically enhanced by transcriptional transactivators.

Drosophila TAF(II)230 and the transcriptional activator VP16 bind competitively to the TATA box-binding domain of the TATA box-binding protein

The transcription initiation factor TFIID, consisting of the TATA box-binding protein (TBP) and many TBP-associated factors (TAFs), plays a central role in both basal and activated transcription. An intriguing finding is that the 80-residue N-terminal region of Drosophila TAF(II)230 [dTAF(II)230-(2-81)] can bind directly to TBP and inhibit its function. Here, studies with mutated forms of TBP demonstrate that dTAF(II)230-(2-81) binds to the concave surface of TBP, which is important for TATA box binding. Previously, it was reported that a point mutation (L114K) on this concave surface destroys the ability of TBP to bind VP16 and to mediate VP16-dependent activation in vitro, but has no effect on basal transcription. Importantly, the same TBP mutation eliminates TBP binding to dTAF(II)230-(2-81). Consistent with these effects of the L114K mutation, dTAF(II)230-(2-81) and the VP16 activation domain compete for binding to wild-type TBP. These results indicate that transcriptional regulation may involve, in part, competitive interactions between transcriptional activators and TAFs on the TBP surface.

Analysis of co-crystal structures to identify the stereochemical determinants of the orientation of TBP on the TATA box

Possible stereochemical determinants of the orientation of TBP on the TATA box are discussed using the crystal coordinates of TBP-TATA complexes, which have been determined by other groups. The C-terminal half of the TBP beta-sheet interacts with the TATA site of the DNA, and the N-terminal half with the A-rich site, so that the two sites with distinct curvatures produce a unique fit. Although chemical contacts take place between one side of the beta-sheet and the DNA minor groove, the interaction seems to be facilitated indirectly by the characteristics of the other side of the beta-sheet and the DNA major groove. Thus, Ala71, Leu162 and Pro190 differentiate the curvature of the beta-sheet in the N- and C-halves. The methyl positions in the DNA major groove modulate the bendability of the two DNA sites by using differences in the rolling capacity of TA and AT compared with PyT, and in the shifting capacity of AT compared with TT. The deformations of the first steps (TA and PyT) in the two sites are the largest and thus are important for the overall bending of the DNA. The differences between the two DNA sites are greatest at the second steps (AT and TT) and so these are important for determining the orientation of TBP.

Mutations on the DNA-binding surface of TATA-binding protein can specifically impair the response to acidic activators in vivo

The TATA-binding protein (TBP) contains a concave surface that interacts specifically with TATA promoter elements and a convex surface that mediates protein-protein interactions with general and gene-specific transcription factors. Biochemical experiments suggest that interactions between activator proteins and TBP are important in stimulating transcription by the RNA polymerase II machinery. To gain insight into the role of TBP in mediating transcriptional activation in vivo, we implemented a genetic strategy in Saccharomyces cerevisiae that involved the use of a TBP derivative with altered specificity for TATA elements. By genetically screening a set of TBP mutant libraries that were biased to the convex surface that mediates protein-protein interactions, we identified TBP derivatives that are impaired in the response to three acidic activators (Gcn4, Gal4, and Ace1) but appear normal for constitutive polymerase II transcription. A genetic complementation assay indicates that the activation-defective phenotypes reflect specific functional properties of the TBP derivatives rather than an indirect effect on transcription. Surprisingly, three of the four activation-defective mutants affect residues that directly contact DNA. Moreover, all four mutants are defective for TATA element binding, but they interact normally with an acidic activation domain and TFIIB. In addition, we show that a subset of TBP derivatives with mutations on the DNA-binding surface of TBP are also compromised in their responses to acidic activators in vivo. These observations suggest that interactions at the TBP-TATA element interface can specifically affect the response to acidic activator proteins in vivo.

An inverted TATA box directs downstream transcription of the bone sialoprotein gene

The orientation of the TATA box is thought to direct downstream transcription of eukaryotic genes by RNA polymerase II. However, the putative TATA box in the promoter of the bone sialoprotein (BSP) gene, which codes for a tissue-specific and developmentally regulated bone matrix protein, is inverted (5'-TTTATA-3') relative to the consensus TATA box sequence (5'-TATAAA-3') and is overlapped by a vitamin D3-response element. Here we show that the inverted TATA sequence in the rat BSP gene binds to recombinant TATA-box-binding protein (TBP) with an affinity similar to that observed with the consensus TATA box, and site-directed point mutations in the inverted TATA sequence (mutating TTTATA into TCTCTA) abrogate both TBP binding and BSP promoter activity. However, when the inverted TATA sequence is changed to a canonical TATAAA, the TBP- and vitamin D3 receptor-binding properties together with the BSP promoter activity are retained. In addition, we found that the TBP is required to reconstitute in vitro transcription driven by the BSP promoter. These studies, which have revealed a naturally occurring inverted TATA box that can bind TBP and direct downstream transcription, demonstrate that the orientation of the TATA box does not determine the direction of transcription in higher eukaryotic genes. Consequently, the inverted TATA box that is conserved in the human, rat and mouse BSP gene promoters will provide an excellent in vivo model to investigate the polarity of the transcription factor IID-DNA complex and its relation to downstream transcription.

Promoter-dependent photocross-linking of the acidic transcriptional activator E2F-1 to the TATA-binding protein

Sequence-specific transcriptional activators, such as the human factor E2F-1, increase the rate of initiation of transcription by RNA polymerase II, possibly by contacting one or more of the RNA polymerase II-associated general initiation factors. One candidate target of transactivators is the TATA-binding protein (TBP), which, when bound to a promoter, nucleates the formation of a preinitiation complex. Previous studies using affinity chromatography techniques have shown that the activation domains of certain activators, including the acidic activation domain of E2F-1, can interact with TBP in the absence of DNA. Using a site-directed photoaffinity cross-linking approach, we demonstrate here that the activation domain of the chimeric activator LexA-E2F-1 can be cross-linked to TBP when both factors are bound to a transcriptionally responsive RNA polymerase II promoter. Mutations within the activation domain of LexA-E2F-1 that impaired its ability to activate transcription in vitro were found to reduce cross-linking of LexA-E2F-1 to TBP. The association of initiation factor TFIIB with the TBP-promoter complex did not preclude this promoter-dependent cross-linking to LexA-E2F-1; however, this cross-linking was promoter-independent. In contrast, TFIIA strongly inhibited the promoter-dependent cross-linking of LexA-E2F-1 to TBP. These results directly demonstrate that acidic activators such as E2F-1 can interact with TBP during the earliest stages in the assembly of an RNA polymerase II preinitiation complex.

TATA-binding protein residues implicated in a functional interplay between negative cofactor NC2 (Dr1) and general factors TFIIA and TFIIB

The TATA-binding protein (TBP) plays a key role in transcription initiation. Several negative cofactors (NC1, NC2, and Dr1) are known to interact with TBP in a manner that prevents productive interactions of transcription factors TFIIA and TFIIB with promoter-bound TBP. To gain insights into the regulatory interplay on the surface of TBP, we have employed mutant forms of TBP to identify amino acid residues important for interactions with the negative regulatory cofactor NC2 and the general factor TFIIB. The results show the involvement of distinct domains of TBP in these interactions. Residues (Lys-133, Lys-145, and Lys-151) in the basic repeat region are important for interactions with NC2, as well as with TFIIA (Buratowski, S., and Zhou, H. (1992) Science 255, 1130-1132; Lee, D. K., DeJong, J., Hashimoto, S., Horikoshi, M., and Roeder, R. G. (1992) Mol. Cell. Biol. 12, 5189-5196), whereas a residue (Leu-189) in the second stirrup-like loop spanning S2' and S3' is required for interaction with TFIIB. In addition, we demonstrate that NC2 is identical to the previously cloned negative cofactor Dr1. The implications of these results for TBP structure and function are discussed.

GAL4 interacts with TATA-binding protein and coactivators

A major goal in understanding eukaryotic gene regulation is to identify the target(s) of transcriptional activators. Efforts to date have pointed to various candidates. Here we show that a 34-amino-acid peptide from the carboxy terminus of GAL4 is a strong activation domain (AD) and retains at least four proteins from a crude extract: the negative regulator GAL80, the TATA-binding protein (TBP), and the putative coactivators SUG1 and ADA2. TFIIB was not retained. Concentrating on TBP, we demonstrate in in vitro binding assays that its interaction with the AD is specific, direct, and salt stable up to at least 1.6 M NaCl. The effects of mutations in the GAL4 AD on transcriptional activation in vivo correlate with their affinities to TBP. A point mutation (L114K) in yeast TBP, which has been shown to compromise the mutant protein in both binding to the VP16 AD domain and activated transcription in vitro, reduces the affinity to the GAL4 AD to the same degree as to the VP16 AD. This suggests that these two prototypic activators make similar contacts with TBP.

Multiple regions of TBP participate in the response to transcriptional activators in vivo

We used mutant yeast and human TBP molecules with an altered DNA-binding specificity to examine the role of TBP in transcriptional activation in vivo. We show that yeast TBP is functionally equivalent to human TBP for response to numerous transcriptional activators in human cells, including those that do not function in yeast. Despite the extensive conservation of TBP, its ability to respond to transcriptional activators in vivo is curiously resistant to clustered sets of alanine substitution mutations in different regions of the protein, including those that disrupt DNA binding and basal transcription in vitro. Combined sets of these mutations, however, can attenuate the in vivo activity of TBP and can differentially affect response to different activation domains. Although the activity of TBP mutants in vivo did not correlate with DNA binding or basal transcription in vitro, it did correlate with binding in vitro to the largest subunit of TFIID, hTAFII250. Together, these data suggest that TBP utilizes multiple interactions across its surface to respond to RNA polymerase II transcriptional activators in vivo; some of these interactions appear to involve recruitment of TBP into TFIID, whereas others are involved in response to specific types of transcriptional activators.

1.9 A resolution refined structure of TBP recognizing the minor groove of TATAAAAG

The three-dimensional structure of a TATA box-binding protein (TBP) from Arabidopsis thaliana complexed with a fourteen base pair oligonucleotide bearing the Adenovirus major late promoter TATA element has been refined at 1.9 A resolution, giving a final crystallographic R-factor of 19.4%. Binding of the monomeric, saddle-shaped alpha/beta protein induces an unprecedented conformational change in the DNA. A detailed structural and functional analysis of this unusual protein-DNA complex is presented, with particular emphasis on the mechanisms of DNA deformation, TATA element recognition, and preinitiation complex assembly.

The TATA-binding protein: a general transcription factor in eukaryotes and archaebacteria

The TATA-binding protein TBP appears to be essential for all transcription in eukaryotic cell nuclei, which suggests that its function was established early in evolution. Archaebacteria constitute a kingdom of organisms distinct from eukaryotes and eubacteria. Archaebacterial gene regulatory sequences often map to TATA box-like motifs. Here it is shown that the archaebacterium Pyrococcus woesei expresses a protein with structural and functional similarity to eukaryotic TBP molecules. This suggests that TBP's role in transcription was established before the archaebacterial and eukaryotic lineages diverged and that the transcription systems of archaebacteria and eukaryotes are fundamentally homologous.

Effects of activation-defective TBP mutations on transcription initiation in yeast

Transcription initiation by RNA polymerase II is effected by an ordered series of general factor interactions with core promoter elements (leading to basal activity) and further regulated by gene-specific factors acting from distal elements. Both the general factor TFIID (refs 2,3), including the constituent TBP (TATA-binding polypeptide) and associated factors, and the interacting factor TFIIB (refs 9-11) have been implicated as targets for various activators. Towards an understanding of the basis for activator function, including the multiplicity of TBP interactions, we have now identified mutations in yeast TBP that selectively block activator (GAL4-VP16)-dependent but not basal transcription. We further show an effect of GAL4-VP16 on TFIIB recruitment to early preinitiation complexes, and that recruitment is disrupted by TBP mutations that impair its interactions with VP16 (L114K), TFIIB (L189K) or an unidentified component (K211L). Thus, GAL4-VP16 function seems to involve both direct interactions with TBP and a corresponding induction (or stabilization) of an activation-specific TBP-TFIIB-promoter complex.

The POU domains of the Oct1 and Oct2 transcription factors mediate specific interaction with TBP

We had previously shown that the ubiquitous Oct1 and the lymphoid-specific Oct2 transcription factors stimulate transcription at the level of stable preinitiation complex formation. We have therefore investigated whether the octamer binding proteins might physically interact with TBP, the TATA box binding protein component of the TFIID factor. By using several different experimental systems we show that TBP efficiently associates with Oct1 and Oct2. The interaction is direct and does not depend on the presence of DNA or additional proteins. N- and C-terminal deletions of the different proteins were used to localize the domains involved in the interaction. We show that the POU homeodomain of Oct2 and the evolutionarily conserved C-terminal core domain of TBP are both required and sufficient for the interaction. The Oct1 POU domain, which is highly homologous to the Oct2 POU domain, likewise mediates interaction with TBP. The interaction can also be observed in vivo, as TBP can be co-precipitated with Oct2 from co-transfected Cos1 cells and TBP co-immunoprecipitates with the endogenous Oct1 from HeLa cells. Co-transfection of human TBP and Oct2 expression vectors into B cells resulted in a synergistic activation of an octamer motif containing promoter.

TATA-binding protein and nuclear differentiation in Tetrahymena thermophila

Unambiguous TATA boxes have not been identified in upstream sequences of Tetrahymena thermophila genes analyzed to date. To begin a characterization of the promoter requirements for RNA polymerase II, the gene encoding TATA-binding protein (TBP) was cloned from this species. The derived amino acid sequence for the conserved C-terminal domain of Tetrahymena TBP is one of the most divergent described and includes a unique 20-amino-acid C-terminal extension. Polyclonal antibodies generated against a fragment of Tetrahymena TBP recognize a 36-kDa protein in macronuclear preparations and also cross-react with yeast and human TBPs. Immunocytochemistry was used to examine the nuclear localization of TBP during growth, starvation, and conjugation (the sexual phase of the life cycle). The transcriptionally active macronuclei stained at all stages of the life cycle. The transcriptionally inert micronuclei did not stain during growth or starvation but surprisingly stained with anti-TBP throughout early stages of conjugation. Anti-TBP staining disappeared from developing micronuclei late in conjugation, corresponding to the onset of transcription in developing macronuclei. Since micronuclei do not enlarge or divide at this time, loss of TBP appears to be an active process. Thus, the transcriptional differences between macro- and micronuclei that arise during conjugation are associated with the loss of a major component of the basal transcription apparatus from developing micronuclei rather than its appearance in developing macronuclei.

TATA-binding protein and nuclear differentiation in Tetrahymena thermophila

Unambiguous TATA boxes have not been identified in upstream sequences of Tetrahymena thermophila genes analyzed to date. To begin a characterization of the promoter requirements for RNA polymerase II, the gene encoding TATA-binding protein (TBP) was cloned from this species. The derived amino acid sequence for the conserved C-terminal domain of Tetrahymena TBP is one of the most divergent described and includes a unique 20-amino-acid C-terminal extension. Polyclonal antibodies generated against a fragment of Tetrahymena TBP recognize a 36-kDa protein in macronuclear preparations and also cross-react with yeast and human TBPs. Immunocytochemistry was used to examine the nuclear localization of TBP during growth, starvation, and conjugation (the sexual phase of the life cycle). The transcriptionally active macronuclei stained at all stages of the life cycle. The transcriptionally inert micronuclei did not stain during growth or starvation but surprisingly stained with anti-TBP throughout early stages of conjugation. Anti-TBP staining disappeared from developing micronuclei late in conjugation, corresponding to the onset of transcription in developing macronuclei. Since micronuclei do not enlarge or divide at this time, loss of TBP appears to be an active process. Thus, the transcriptional differences between macro- and micronuclei that arise during conjugation are associated with the loss of a major component of the basal transcription apparatus from developing micronuclei rather than its appearance in developing macronuclei.

Co-crystal structure of TBP recognizing the minor groove of a TATA element

The three-dimensional structure of a TATA-box binding polypeptide complexed with the TATA element of the adenovirus major late promoter has been determined by X-ray crystallography at 2.25 A resolution. Binding of the saddle-shaped protein induces a conformational change in the DNA, inducing sharp kinks at either end of the sequence TATAAAAG. Between the kinks, the right-handed double helix is smoothly curved and partially unwound, presenting a widened minor groove to TBP's concave, antiparallel beta-sheet. Side-chain/base interactions are restricted to the minor groove, and include hydrogen bonds, van der Waals contacts and phenylalanine-base stacking interactions.

Crystal structure of a yeast TBP/TATA-box complex

The 2.5 A crystal structure of a TATA-box complex with yeast TBP shows that the eight base pairs of the TATA box bind to the concave surface of TBP by bending towards the major groove with unprecedented severity. This produces a wide open, underwound, shallow minor groove which forms a primarily hydrophobic interface with the entire under-surface of the TBP saddle. The severe bend and a positive writhe radically alter the trajectory of the flanking B-form DNA.

Association between proto-oncoprotein Rel and TATA-binding protein mediates transcriptional activation by NF-kappa B

The c-Rel protein is able to associate in vitro and in vivo with the TATA-binding protein (TBP) of the TFIID complex. Coexpression of TBP with c-Rel augments transactivation from the kappa B site in Drosophila Schneider cells. DNA-binding mutants of TBP not only fail to cooperate, but they repress transactivation by c-Rel. There may be a direct communication between kappa B enhancer binding proteins and basal transcription factors which leads to enhanced transcription.

Crystal structure of yeast TATA-binding protein and model for interaction with DNA

The C-terminal 179-aa region of yeast (Saccharomyces cerevisiae) TATA-binding protein (TBP), phylogenetically conserved and sufficient for many functions, formed crystals diffracting to 1.7-A resolution. The structure of the protein, determined by molecular replacement with coordinates from Arabidopsis TBP and refined to 2.6 A, differed from that in Arabidopsis slightly by an angle of about 12 degrees between two structurally nearly identical subdomains, indicative of a degree of conformational flexibility. A model for TBP-DNA interaction is proposed with the following important features: the long dimension of the protein follows the trajectory of the minor groove; two rows of basic residues conserved between the subdomains lie along the edges of the protein in proximity to the DNA phosphates; a band of hydrophobic residues runs down the middle of the groove; and amino acid residues whose mutation alters specificity for the second base of the TATA sequence are juxtaposed to that base.

Transcription factor TFIIB sites important for interaction with promoter-bound TFIID

Transcription initiation factor TFIIB recruits RNA polymerase II to the promoter subsequent to interaction with a preformed TFIID-promoter complex. The domains of TFIIB required for binding to the TFIID-promoter complex and for transcription initiation have been determined. The carboxyl-terminal two-thirds of TFIIB, which contains two direct repeats and two basic residue repeats, is sufficient for interaction with the TFIID-promoter complex. An extra 84-residue amino-terminal region, with no obvious known structural motifs, is required for basal transcription activity. Basic residues within the second basic repeat of TFIIB are necessary for stable interaction with the TFIID-promoter complex, whereas the basic character of the first basic repeat is not. Functional roles of other potential structural motifs are discussed in light of the present study.

Functional dissection of TFIIB domains required for TFIIB-TFIID-promoter complex formation and basal transcription activity

The protein TFIIB is a general transcription initiation factor that interacts with a promoter complex (D.DNA) containing the TATA-binding subunit (TFIID tau, or TBP) of TFIID to facilitate subsequent interaction with RNA polymerase II (ref. 2) through the associated TFIIF (ref. 3). The potential bridging function of TFIIB raises the possibility of two structural domains and emphasizes the importance of TFIIB structure-function studies for a further understanding of preinitiation complex assembly and function. Here we show that human TFIIB (refs 5,6) is comprised of functionally distinct N- and C-terminal domains. The C-terminal domain, containing the direct repeats and associated basic regions, is necessary and sufficient for interaction with the D.DNA complex. By contrast, the N-terminal domain that is dispensable for formation of the TFIID tau-TFIIB-promoter (D.B.DNA) complex is required for subsequent events leading to basal transcription initiation. On the basis of these results, we discuss structural and functional similarities between TFIIB and TFIID tau, which have similar structural organization and motifs.

Functional domains of transcription factor TFIIB

Transcription factor TFIIB is an essential component of the RNA polymerase II initiation complex. TFIIB carries out at least two functions: it interacts directly with the TATA-binding protein (TBP) and helps to recruit RNA polymerase II into the initiation complex. The sequence of TFIIB reveals a potential zinc-binding domain and an imperfect duplication of approximately 70 amino acids. Mutagenesis of cysteine codons within the putative zinc finger results in mutant proteins that bind normally to TBP but are unable to recruit RNA polymerase II-TFIIF into the initiation complex. Changing the two most highly conserved amino acids in the TFIIB repeats reduces the ability of TFIIB to interact with TBP. Therefore, the two functions of TFIIB can be assigned to two separable functional domains of the protein.

Unusual charge configurations in transcription factors of the basic RNA polymerase II initiation complex

A systematic analysis of the primary sequences of the polymerase II initiation complex has revealed unusual charge features in the TFII family proteins. In particular, the proteins TFIIA alpha, TFIIE alpha, and TFIIF carry multiple charge clusters and hyper charge runs, sequence features occurring in < 4% of all (available) eukaryotic proteins. Possible implications for these charge structures are discussed in relation to the assembly and function of the polymerase II transcriptional complex.

Multiple functional domains of human transcription factor IIB: distinct interactions with two general transcription factors and RNA polymerase II

Transcription factor IIB (TFIIB) plays a pivotal role in the formation of transcription-competent initiation complexes. TFIIB was found to interact with the TATA-binding protein, the small subunit of TFIIF, and RNA polymerase II. These interactions require distinct domains in TFIIB. Using the gel mobility-shift assay, it was found that the amino terminus of TFIIB was necessary for the formation of complexes containing RNA polymerase II and TFIIF, whereas the carboxy-terminal domain, which is composed of two imperfect direct repeats and includes a putative amphipathic alpha-helix, was sufficient for the formation of complexes containing the TATA-binding protein and TFIIB (DB complex). Protein-protein interaction analyses demonstrate that the amphipathic alpha-helix in TFIIB is important for the interaction with the TATA-binding protein. Specific residues mapping to the carboxyl terminus of the second direct repeat were found to be crucial for the interaction of TFIIB and RNA polymerase II. The interaction with the small subunit of TFIIF was mapped to the amino terminus of TFIIB, which includes a zinc finger.

An ATP-dependent inhibitor of TBP binding to DNA

An activity in yeast nuclear extracts (termed ADI) is described that inhibits the binding of the TATA-binding protein (TBP) to DNA in an ATP-dependent manner. The effect is reversible, ATP specific, rapid, and is not promoter specific. ADI is specific for TBP because three other protein-DNA complexes are not affected by ADI. The action of ADI is blocked by association of TFIIA with the TBP-DNA complex. ADI activity at the adenovirus major late promoter requires a segment of DNA upstream from the TATA sequence, suggesting that ADI recognizes aspects of both TBP and DNA. The evolutionarily conserved carboxy-terminal domain of TBP is sufficient for ADI recognition, and amino acids in the basic region of TBP are required for ADI action. ADI can repress transcription in vitro in an ATP-dependent manner. In the presence of ADI, both TFIIA and TBP are required to commit a template to transcription. A model of ADI action is proposed, and possible roles of ADI in the regulation of the transcription complex assembly are discussed.

Cofractionation of the TATA-binding protein with the RNA polymerase III transcription factor TFIIIB

We have investigated the requirement for TBP (TATA-binding protein) in transcription mediated by RNA polymerase III (pol III) in fractionated HeLa cell extracts. Two activities, TFIIIB and TFIIIC, found in phosphocellulose fractions PC B and PC C respectively, have been defined as necessary and sufficient, with pol III, for in vitro transcription of tRNA genes. Depletion of TBP from PC B, using antibodies raised against human TBP, is shown to inhibit the pol III transcriptional activity of the fraction. Furthermore, TBP is present in fractions with human TFIIIB activity, and a proportion of TBP cofractionates with TFIIIB over four chromatographic purification steps. TFIIIB fractions are capable of supplying TBP in the form necessary for pol III transcription, and cannot be substituted by fractions containing other TBP complexes or TBP alone. The use of a 5S RNA gene and two tRNA templates supports the general relevance of our findings for pol III gene transcription. Purified TFIIIB activity can also support pol II-mediated transcription, and is found in a complex of approximately 230kD, suggesting that TFIIIB may be the same as the previously characterized B-TFIID complex (1,2). We suggest that transcription by the three RNA polymerases is mediated by distinct TBP-TAF complexes: SL1 and D-TFIID for pol I and pol II respectively, and TFIIIB for pol III.

TFIIA induces conformational changes in TFIID via interactions with the basic repeat

DNA-binding studies with Saccharomyces cerevisiae TFIID point mutants indicated that TFIIA interacts with the basic repeat region of TFIID and induces structural changes. The latter was shown by the ability of TFIIA to compensate for TFIID point mutants defective for DNA binding. Interaction with TFIIA also rendered TFIID binding temperature independent, thus mimicking the effect of removing the nonconserved N terminus of TFIID. In addition, N-terminal truncation of the TFIID point mutants defective for DNA binding mimicked the ability of TFIIA to restore DNA binding of those mutants. Taken together, these results suggest that TFIIA enhances TFIID binding to DNA by eliminating an otherwise inhibitory effect of the nonconserved N terminus of TFIID. Furthermore, analyses of TFIID contact points on DNA and binding studies with TATA-containing oligonucleotide probes showed that TFIIA decreases the effect of sequences flanking the adenovirus major late TATA element on TFIID binding to DNA, suggesting a possible role of TFIIA in allowing TFIID to recognize a wider variety of promoters.

Crystal structure of TFIID TATA-box binding protein

The structure of a central component of the eukaryotic transcriptional apparatus, a TATA-box binding protein (TBP or TFIID tau) from Arabidopsis thaliana, has been determined by X-ray crystallography at 2.6 A resolution. This highly symmetric alpha/beta structure contains a new DNA-binding fold, resembling a molecular 'saddle' that sits astride the DNA. The DNA-binding surface is a curved, antiparallel beta-sheet. When bound to DNA, the convex surface of the saddle would be presented for interaction with other transcription initiation factors and regulatory proteins.

TFIIA induces conformational changes in TFIID via interactions with the basic repeat

DNA-binding studies with Saccharomyces cerevisiae TFIID point mutants indicated that TFIIA interacts with the basic repeat region of TFIID and induces structural changes. The latter was shown by the ability of TFIIA to compensate for TFIID point mutants defective for DNA binding. Interaction with TFIIA also rendered TFIID binding temperature independent, thus mimicking the effect of removing the nonconserved N terminus of TFIID. In addition, N-terminal truncation of the TFIID point mutants defective for DNA binding mimicked the ability of TFIIA to restore DNA binding of those mutants. Taken together, these results suggest that TFIIA enhances TFIID binding to DNA by eliminating an otherwise inhibitory effect of the nonconserved N terminus of TFIID. Furthermore, analyses of TFIID contact points on DNA and binding studies with TATA-containing oligonucleotide probes showed that TFIIA decreases the effect of sequences flanking the adenovirus major late TATA element on TFIID binding to DNA, suggesting a possible role of TFIIA in allowing TFIID to recognize a wider variety of promoters.