Characterization of sua7 mutations defines a domain of TFIIB involved in transcription start site selection in yeast

Structural perspective on mutations affecting the function of multisubunit RNA polymerases

High-resolution crystallographic structures of multisubunit RNA polymerases (RNAPs) have increased our understanding of transcriptional mechanisms. Based on a thorough review of the literature, we have compiled the mutations affecting the function of multisubunit RNA polymerases, many of which having been generated and studied prior to the publication of the first high-resolution structure, and highlighted the positions of the altered amino acids in the structures of both the prokaryotic and eukaryotic enzymes. The observations support many previous hypotheses on the transcriptional process, including the implication of the bridge helix and the trigger loop in the processivity of RNAP, the importance of contacts between the RNAP jaw-lobe module and the downstream DNA in the establishment of a transcription bubble and selection of the transcription start site, the destabilizing effects of ppGpp on the open promoter complex, and the link between RNAP processivity and termination. This study also revealed novel, remarkable features of the RNA polymerase catalytic mechanisms that will require additional investigation, including the putative roles of fork loop 2 in the establishment of a transcription bubble, the trigger loop in start site selection, and the uncharacterized funnel domain in RNAP processivity.

Determinants of transcription initiation by archaeal RNA polymerase

Transcription in Archaea is catalyzed by an RNA polymerase that is most similar to eukaryotic RNA polymerases both in subunit composition and in transcription initiation factor requirements. Recent studies on archaeal transcription in diverse members of this domain have contributed new details concerning the functions of promoters and transcription factors in guiding initiation by RNA polymerase, and phylogenetic arguments have allowed modeling of archaeal transcription initiation complexes by comparison with recently described models of eukaryotic and bacterial transcription initiation complexes. Important new advances in reconstitution of archaeal transcription complexes from fully recombinant components is permitting testing of hypotheses derived from and informed by these structural models, and will help bring the study of archaeal transcription to the levels of understanding currently enjoyed by bacterial and eukaryotic RNA polymerase II transcription.

Direct modulation of RNA polymerase core functions by basal transcription factors

Archaeal RNA polymerases (RNAPs) are recruited to promoters through the joint action of three basal transcription factors: TATA-binding protein, TFB (archaeal homolog of TFIIB), and TFE (archaeal homolog of TFIIE). Our results demonstrate several new insights into the mechanisms of TFB and TFE during the transcription cycle. (i) The N-terminal Zn ribbon of TFB displays a surprising degree of redundancy for the recruitment of RNAP during transcription initiation in the archaeal system. (ii) The B-finger domain of TFB participates in transcription initiation events by stimulating abortive and productive transcription in a recruitment-independent function. TFB thus combines physical recruitment of the RNAP with an active role in influencing the catalytic properties of RNAP during transcription initiation. (iii) TFB mutations are complemented by TFE, thereby demonstrating that both factors act synergistically during transcription initiation. (iv) An additional function of TFE is to dynamically alter the nucleic acid-binding properties of RNAP by stabilizing the initiation complex and destabilizing elongation complexes.

The role of the transcription bubble and TFIIB in promoter clearance by RNA polymerase II

We have studied promoter clearance at a series of RNA polymerase II promoters with varying spacing of the TATA box and start site. We find that regardless of promoter spacing, the upstream edge of the transcription bubble forms 20 bp from TATA. The bubble expands downstream until 18 bases are unwound and the RNA is at least 7 nt long, at which point the upstream approximately 8 bases of the bubble abruptly reanneal (bubble collapse). If either bubble size or transcript length is insufficient, bubble collapse cannot occur. Bubble collapse coincides with the end of the requirement for the TFIIH helicase for efficient transcript elongation. We also provide evidence that bubble collapse suppresses pausing at +7 to +9 caused by the presence of the B finger segment of TFIIB within the complex. Our results indicate that bubble collapse defines the RNA polymerase II promoter clearance transition.

A functional role for the switch 2 region of yeast RNA polymerase II in transcription start site utilization and abortive initiation

RNA polymerase II (RNAPII) is responsible for the synthesis of mRNA from eukaryotic protein-encoding genes. In this study, site-directed mutagenesis was employed to probe the function of residues within the Saccharomyces cerevisiae RNAPII active center in the mechanism of transcription start site utilization. We report here the identification of two mutations in the switch 2 region, rpb1-K332A and rpb1-R344A, which conferred conditional growth properties and downstream shifts in start site utilization. Analyses of double mutant strains demonstrated functional interactions between these switch 2 mutations and a mutation in the largest subunit of transcription factor IIF (TFIIF) that confers upstream shifts in start site usage. Importantly, biochemical analyses demonstrated that purified Rpb1-R344A mutant polymerase exhibited impaired ability to stabilize a short RNA-DNA hybrid in the active center, an increased frequency of abortive transcription in runoff assays, and both a downstream shift and increased abortive initiation in reconstituted transcription assays. These results provide evidence for a role of switch 2 during start site utilization and indicate that RNA-DNA hybrid stability at the 3'-end of the transcript is a determinant in this process. We discuss these results within the context of a proposed model regarding the concerted roles of RNAPII, TFIIB, and TFIIF during mRNA 5'-end formation in S. cerevisiae.

High-resolution protein-DNA contacts for the yeast RNA polymerase II general transcription machinery

We used site-specific protein-DNA photo-cross-linking to define contact points between Saccharomyces cerevisiae RNA polymerase II (RNAP II) and the general transcription factors TBP, TFIIB, and TFIIF on promoter DNA. We present three key findings: (i) the overall pattern of cross-link sites is remarkably similar between the yeast and the previously described human system, even though transcription initiates downstream of the DNA-TBP-TFIIB-RNAP II-TFIIF complex in the S. cerevisiae system; (ii) the yeast Rpb7 subunit of RNAP II forms strong and reproducible cross-links to both strands of promoter DNA; and (iii) a TFIIB arginine-78 to cysteine replacement (R78C), which shifts start site selection downstream of normal, does not affect TFIIB-DNA cross-links prior to promoter melting but instead affects downstream TFIIF-DNA interactions. These results support the premise that the overall structure of the RNAP II preinitiation complex is similar in all eukaryotes and imply that yeast RNAP II is able to scan template DNA downstream of the preinitiation complex for acceptable start sites. The novel Rpb7-DNA contact sites imply that either promoter DNA does not follow a straight path from TATA to the initiation site or the topology of Rpb7 within the DNA-TBP-TFIIB-RNAP II-TFIIF complex is different from that defined in the 12-subunit RNAP II X-ray structure. We discuss the implications of these results for the mechanism of preinitiation complex assembly and promoter melting.

The Schizosaccharomyces pombe open promoter bubble: mammalian-like arrangement and properties

The fission yeast Schizosaccharomyces pombe is often used as a genetic system to model processes that apply to higher cells. Here S.pombe was used to study promoter DNA opening and transcription initiation by RNA polymerase II. The melted region within the adh promoter is about 20 bp in size and has the start site near its center. This arrangement is similar to that at the AdML promoter but different from that in Saccharomyces cerevisiae. Although expression of human TFIIB shifts the start site to the nearby human position, it does not change the location of the bubble. The start site shift is directed by the C terminus of human TFIIB, in contrast to expectations from S.cerevisiae. The creation of the bubble requires the ATPase motifs of XPB. Overall, the data show that promoter melting and initiation in fission yeast is much more similar to humans than to budding yeast.

Functional interaction between TFIIB and the Rpb2 subunit of RNA polymerase II: implications for the mechanism of transcription initiation

The general transcription factor TFIIB is required for accurate initiation, although the mechanism by which RNA polymerase II (RNAP II) identifies initiation sites is not well understood. Here we describe results from genetic and biochemical analyses of an altered form of yeast TFIIB containing an arginine-78 --> cysteine (R78C) replacement in the "B-finger" domain. TFIIB R78C shifts start site selection downstream of normal and confers a cold-sensitive growth defect (Csm(-)). Suppression of the R78C Csm(-) phenotype identified a functional interaction between TFIIB and the Rpb2 subunit of RNAP II and defined a novel role for Rpb2 in start site selection. The rpb2 suppressor encodes a glycine-369 --> serine (G369S) replacement, located in the "lobe" domain of Rpb2 and near the Rpb9 subunit, which was identified previously as an effector of start site selection. The Rpb2-Rpb9 "lobe-jaw" region of RNAP II is downstream of the catalytic center and distal to the site of RNAP II-TFIIB interaction. A TFIIB R78C mutant extract was defective for promoter-specific run-on transcription but yielded an altered pattern of abortive initiation products, indicating that the R78C defect does not preclude initiation. The sua7-3 rpb2-101 double mutant was sensitive to 6-azauracil in vivo and to nucleoside triphosphate substrate depletion in vitro. In the context of the recent X-ray structure of the yeast RNAP II-TFIIB complex, these results define a functional interaction between the B-finger domain of TFIIB and the distal lobe-jaw region of RNAP II and provide insight into the mechanism of start site selection.

Structural Basis of Transcription: An RNA Polymerase II-TFIIB Cocrystal at 4.5 Angstroms

The structure of the general transcription factor IIB (TFIIB) in a complex with RNA polymerase II reveals three features crucial for transcription initiation: an N-terminal zinc ribbon domain of TFIIB that contacts the "dock" domain of the polymerase, near the path of RNA exit from a transcribing enzyme; a "finger" domain of TFIIB that is inserted into the polymerase active center; and a C-terminal domain, whose interaction with both the polymerase and with a TATA box-binding protein (TBP)-promoter DNA complex orients the DNA for unwinding and transcription. TFIIB stabilizes an early initiation complex, containing an incomplete RNA-DNA hybrid region. It may interact with the template strand, which sets the location of the transcription start site, and may interfere with RNA exit, which leads to abortive initiation or promoter escape. The trajectory of promoter DNA determined by the C-terminal domain of TFIIB traverses sites of interaction with TFIIE, TFIIF, and TFIIH, serving to define their roles in the transcription initiation process.

FRET evidence for a conformational change in TFIIB upon TBP-DNA binding

As a critical step of the preinitiation complex assembly in transcription, the general transcription factor TFIIB forms a complex with the TATA-box binding protein (TBP) bound to a promoter element. Transcriptional activators such as the herpes simplex virus VP16 facilitate this complex formation through conformational activation of TFIIB, a focal molecule of transcriptional initiation and activation. Here, we used fluorescence resonance energy transfer to investigate conformational states of human TFIIB fused to enhanced cyan fluorescent protein and enhanced yellow fluorescent protein at its N- and C-terminus, respectively. A significant reduction in fluorescence resonance energy transfer ratio was observed when this fusion protein, hereafter named CYIIB, was mixed with promoter-loaded TBP. The rate for the TFIIB-TBP-DNA complex formation is accelerated drastically by GAL4-VP16 and is also dependent on the type of promoter sequences. These results provide compelling evidence for a 'closed-to-open' conformational change of TFIIB upon binding to the TBP-DNA complex, which probably involves alternation of the spatial orientation between the N-terminal zinc ribbon domain and the C-terminal conserved core domain responsible for direct interactions with TBP and a DNA element.

Direct interaction of TFIIB and the IE protein of equine herpesvirus 1 is required for maximal trans-activation function

Recently, we reported that the immediate-early (IE) protein of equine herpesvirus 1 (EHV-1) associates with transcription factor TFIIB [J. Virol. 75 (2001), 10219]. In the current study, the IE protein purified as a glutathione-S-transferase (GST) fusion protein was shown to interact directly with purified TFIIB in GST-pulldown assays. A panel of TFIIB mutants employed in protein-binding assays revealed that residues 125 to 174 within the first direct repeat of TFIIB mediate its interaction with the IE protein. This interaction is physiologically relevant as transient transfection assays demonstrated that (1). exogenous native TFIIB did not perturb IE protein function, and (2). ectopic expression of a TFIIB mutant that lacked the IE protein interactive domain significantly diminished the ability of the IE protein to trans-activate EHV-1 promoters. These results suggest that an interaction of the IE protein with TFIIB is an important aspect of the regulatory role of the IE protein in the trans-activation of EHV-1 promoters.

Topography of the euryarchaeal transcription initiation complex

Transcription in the Archaea is carried out by RNA polymerases and transcription factors that are highly homologous to their eukaryotic counterparts, but little is known about the structural organization of the archaeal transcription complex. To address this, transcription initiation complexes have been formed with Pyrococcus furiosus transcription factors (TBP and TFB1), RNA polymerase, and a linear DNA fragment containing a strong promoter. The arrangement of proteins from base pair -35 to +20 (relative to the transcriptional start site) has been analyzed by photochemical protein-DNA cross-linking. TBP cross-links to the TATA box and TFB1 cross-links both upstream and downstream of the TATA box, as expected, but the sites of most prominent TFB1 cross-linking are located well downstream of the TATA box, reaching as far as the start site of transcription, suggesting a role for TFB1 in initiation of transcription that extends beyond polymerase recruitment. These cross-links indicate the transcription factor orientation in the initiation complex. The pattern of cross-linking of four RNA polymerase subunits (B, A', A", and H) to the promoter suggests a path for promoter DNA relative to the RNA polymerase surface in this archaeal transcription initiation complex. In addition, an unidentified protein approximately the size of TBP cross-links to the non-transcribed DNA strand near the upstream edge of the transcription bubble. Cross-linking is specific to the polymerase-containing initiation complex and requires the gdh promoter TATA box. The location of this protein suggests that it, like TFB1, could also have a role in transcription initiation following RNA polymerase recruitment.

Transcription factor B contacts promoter DNA near the transcription start site of the archaeal transcription initiation complex

Transcription initiation in all three domains of life requires the assembly of large multiprotein complexes at DNA promoters before RNA polymerase (RNAP)-catalyzed transcript synthesis. Core RNAP subunits show homology among the three domains of life, and recent structural information supports this homology. General transcription factors are required for productive transcription initiation complex formation. The archaeal general transcription factors TATA-element-binding protein (TBP), which mediates promoter recognition, and transcription factor B (TFB), which mediates recruitment of RNAP, show extensive homology to eukaryal TBP and TFIIB. Crystallographic information is becoming available for fragments of transcription initiation complexes (e.g. RNAP, TBP-TFB-DNA, TBP-TFIIB-DNA), but understanding the molecular topography of complete initiation complexes still requires biochemical and biophysical characterization of protein-protein and protein-DNA interactions. In published work, systematic site-specific protein-DNA photocrosslinking has been used to define positions of RNAP subunits and general transcription factors in bacterial and eukaryal initiation complexes. In this work, we have used systematic site-specific protein-DNA photocrosslinking to define positions of RNAP subunits and general transcription factors in an archaeal initiation complex. Employing a set of 41 derivatized DNA fragments, each having a phenyl azide photoactivable crosslinking agent incorporated at a single, defined site within positions -40 to +1 of the gdh promoter of the hyperthermophilic marine archaea, Pyrococcus furiosus (Pf), we have determined the locations of PfRNAP subunits PfTBP and PfTFB relative to promoter DNA. The resulting topographical information supports the striking homology with the eukaryal initiation complex and permits one major new conclusion, which is that PfTFB interacts with promoter DNA not only in the TATA-element region but also in the transcription-bubble region, near the transcription start site. Comparison with crystallographic information implicates the PfTFB N-terminal domain in the interaction with the transcription-bubble region. The results are discussed in relation to the known effects of substitutions in the TFB and TFIIB N-terminal domains on transcription initiation and transcription start-site selection.

Yeast RNA polymerase II lacking the Rpb9 subunit is impaired for interaction with transcription factor IIF

Previous studies have shown that transcription factors IIB (TFIIB), IIF (TFIIF), and RNA polymerase II (RNAPII) play important roles in determining the position of mRNA 5'-ends in the yeast Saccharomyces cerevisiae. Yeast strains containing a deletion of the small, nonessential Rpb9 subunit of RNAPII exhibit an upstream shift in the positions of mRNA 5'-ends, whereas mutation of the large subunit of yeast TFIIF (Tfg1) can suppress downstream shifts that are conferred by mutations in TFIIB. In this study, we report an approach for the production of functional recombinant yeast holo-TFIIF (Tfg1-Tfg2 complex) and use of the recombinant protein in both reconstituted transcription assays and gel mobility shifts in order to investigate the biochemical alterations associated with the deltaRpb9 polymerase. The results demonstrated that upstream shifts in the positions of mRNA 5'-ends could be conferred by the deltaRpb9 RNAPII in transcription reactions reconstituted with highly purified yeast general transcription factors and, importantly, that these shifts are associated with an impaired interaction between the DeltaRpb9 polymerase and TFIIF. Potential mechanisms by which an altered interaction between the DeltaRpb9 RNAPII and TFIIF confers an upstream shift in the positions of mRNA 5'-ends are discussed.

Binding of TFIIB to RNA Polymerase II

RNA polymerase II (Pol II) is recruited to promoters by interaction with general transcription factors. The zinc ribbon domain of the general factor TFIIB is essential for Pol II recruitment. Site-specific photocrosslinking and directed hydroxyl radical probing were used to map the location of the TFIIB zinc ribbon domain on Pol II within the transcription preinitiation complex (PIC). These results, along with mutational analysis, suggest that in the PIC, the TFIIB ribbon domain interacts with a surface of the Pol II Dock domain where it overlaps the RNA exit point. This surface is best conserved in polymerases that require a TFIIB-like factor. Our results suggest a general mechanism for interaction of TFIIB-like factors and RNA polymerases and a mechanism for the function of the ribbon domain.

The role of transcription initiation factor IIIB subunits in promoter opening probed by photochemical cross-linking

The core transcription initiation factor (TF) IIIB recruits its conjugate RNA polymerase (pol) III to the promoter and also plays an essential role in promoter opening. TFIIIB assembled with certain deletion mutants of its Brf1 and Bdp1 subunits is competent in pol III recruitment, but the resulting preinitiation complex does not open the promoter. Whether Brf1 and Bdp1 participate in opening the promoter by direct DNA interaction (as sigma subunits of bacterial RNA polymerases do) or indirectly by their action on pol III has been approached by site-specific photochemical protein-DNA cross-linking of TFIIIB-pol III-U6 RNA gene promoter complexes. Brf1, Bdp1, and several pol III subunits can be cross-linked to the nontranscribed strand of the U6 promoter at base pair -9/-8 and +2/+3 (relative to the transcriptional start as +1), respectively the upstream and downstream ends of the DNA segment that opens up into the transcription bubble. Cross-linking of Bdp1 and Brf1 is detected at 0 degrees C in closed preinitiation complexes and at 30 degrees C in complexes that are partly open, but also it is detected in mutant TFIIIB-pol III-DNA complexes that are unable to open the promoter. In contrast, promoter opening-defective TFIIIB mutants generate significant changes of cross-linking of polymerase subunits. The weight of this evidence argues in favor of an indirect mode of action of TFIIIB in promoter opening.

Hypomutable regions of yeast TFIIB in a unigenic evolution test represent structural domains

As genome sequences of many organisms - including humans - are being decoded, there is a great need for genetic tools to analyze newly discovered genes/proteins. A 'unigenic evolution' approach has been previously proposed for dissecting protein domains, which is based on the assumption that functionally important regions of a protein may tolerate missense mutations less well than other regions. We describe a unigenic evolution analysis of general transcription factor IIB (TFIIB) - a protein that is well characterized both structurally and functionally - to better understand the molecular basis of this genetic approach. The overall distribution profile of hypomutable regions within yeast TFIIB correlates extremely well with the known compact structural domains, suggesting that the unigenic evolution approach can help reveal structural properties of a protein. We further show that a small region located immediately carboxyl-terminal to the zinc ribbon motif is functionally important despite its strong hypermutability. Our study further demonstrates the usefulness of the unigenic evolution approach in dissecting protein domains, but suggests that the mutability of different regions of a protein in such a test is determined primarily by their structural properties.

Basal transcription factors

The functions of the basal transcription factors involved in RNA polymerase II dependent transcription have been the focus of many years of biochemical analysis. Recent advances have shed some light on the structure of these factors, how conformational changes and intramolecular interactions regulate activity, and have revealed an expanded role for TFIIH in nuclear transcription.

Interdependent interactions between TFIIB, TATA binding protein, and DNA

Temperature-sensitive mutants of TFIIB that are defective for essential interactions were isolated. One mutation (G204D) results in disruption of a protein-protein contact between TFIIB and TATA binding protein (TBP), while the other (K272I) disrupts an interaction between TFIIB and DNA. The TBP gene was mutagenized, and alleles that suppress the slow-growth phenotypes of the TFIIB mutants were isolated. TFIIB with the G204D mutation [TFIIB(G204D)] was suppressed by hydrophobic substitutions at lysine 239 of TBP. These changes led to increased affinity between TBP and TFIIB. TFIIB(K272I) was weakly suppressed by TBP mutants in which K239 was changed to hydrophobic residues. However, this mutant TFIIB was strongly suppressed by conservative substitutions in the DNA binding surface of TBP. Biochemical characterization showed that these TBP mutants had increased affinity for a TATA element. The TBPs with increased affinity could not suppress TFIIB(G204D), leading us to propose a two-step model for the interaction between TFIIB and the TBP-DNA complex.

Core promoter-dependent TFIIB conformation and a role for TFIIB conformation in transcription start site selection

The general transcription factor TFIIB plays a central role in the selection of the transcription initiation site. The mechanisms involved are not clear, however. In this study, we analyze core promoter features that are responsible for the susceptibility to mutations in TFIIB and cause a shift in the transcription start site. We show that TFIIB can modulate both the 5' and 3' parameters of transcription start site selection in a manner dependent upon the sequence of the initiator. Mutations in TFIIB that cause aberrant transcription start site selection concentrate in a region that plays a pivotal role in modulating TFIIB conformation. Using epitope-specific antibody probes, we show that a TFIIB mutant that causes aberrant transcription start site selection assembles at the promoter in a conformation different from that for wild-type TFIIB. In addition, we uncover a core promoter-dependent effect on TFIIB conformation and provide evidence for novel sequence-specific TFIIB promoter contacts.

Promoter-specific shifts in transcription initiation conferred by yeast TFIIB mutations are determined by the sequence in the immediate vicinity of the start sites

The general transcription factor IIB (TFIIB) is required for transcription of class II genes by RNA polymerase II. Previous studies demonstrated that mutations in the Saccharomyces cerevisiae SUA7 gene, which encodes TFIIB, can alter transcription initiation patterns in vivo. To further delineate the functional domain and residues of TFIIB involved in transcription start site utilization, a genetic selection was used to isolate S. cerevisiae TFIIB mutants exhibiting downstream shifts in transcription initiation in vivo. Both dominant and recessive mutations conferring downstream shifts were identified at multiple positions within a highly conserved homology block in the N-terminal region of the protein. The TFIIB mutations conferred downstream shifts in transcription initiation at the ADH1 and CYC1 promoters, whereas no significant shifts were observed at the HIS3 promoter. Analysis of a series of ADH1-HIS3 hybrid promoters and variant ADH1 and HIS3 promoters containing insertions, deletions, or site-directed base substitutions revealed that the feature that renders a promoter sensitive to TFIIB mutations is the sequence in the immediate vicinity of the normal start sites. We discuss these results in light of possible models for the mechanism of start site utilization by S. cerevisiae RNA polymerase II and the role played by TFIIB.

Functional interaction between Ssu72 and the Rpb2 subunit of RNA polymerase II in Saccharomyces cerevisiae

SSU72 is an essential gene encoding a phylogenetically conserved protein of unknown function that interacts with the general transcription factor TFIIB. A recessive ssu72-1 allele was identified as a synthetic enhancer of a TFIIB (sua7-1) defect, resulting in a heat-sensitive (Ts(-)) phenotype and a dramatic downstream shift in transcription start site selection. Here we describe a new allele, ssu72-2, that confers a Ts(-) phenotype in a SUA7 wild-type background. In an effort to further define Ssu72, we isolated suppressors of the ssu72-2 mutation. One suppressor is allelic to RPB2, the gene encoding the second-largest subunit of RNA polymerase II (RNAP II). Sequence analysis of the rpb2-100 suppressor defined a cysteine replacement of the phylogenetically invariant arginine residue at position 512 (R512C), located within homology block D of Rpb2. The ssu72-2 and rpb2-100 mutations adversely affected noninduced gene expression, with no apparent effects on activated transcription in vivo. Although isolated as a suppressor of the ssu72-2 Ts(-) defect, rpb2-100 enhanced the transcriptional defects associated with ssu72-2. The Ssu72 protein interacts directly with purified RNAP II in a coimmunoprecipitation assay, suggesting that the genetic interactions between ssu72-2 and rpb2-100 are a consequence of physical interactions. These results define Ssu72 as a highly conserved factor that physically and functionally interacts with the RNAP II core machinery during transcription initiation.

Structure of a (Cys3His) zinc ribbon, a ubiquitous motif in archaeal and eucaryal transcription

Transcription factor IIB (TFIIB) is an essential component in the formation of the transcription initiation complex in eucaryal and archaeal transcription. TFIIB interacts with a promoter complex containing the TATA-binding protein (TBP) to facilitate interaction with RNA polymerase II (RNA pol II) and the associated transcription factor IIF (TFIIF). TFIIB contains a zinc-binding motif near the N-terminus that is directly involved in the interaction with RNA pol II/TFIIF and plays a crucial role in selecting the transcription initiation site. The solution structure of the N-terminal residues 2-59 of human TFIIB was determined by multidimensional NMR spectroscopy. The structure consists of a nearly tetrahedral Zn(Cys)3(His)1 site confined by type I and "rubredoxin" turns, three antiparallel beta-strands, and disordered loops. The structure is similar to the reported zinc-ribbon motifs in several transcription-related proteins from archaea and eucarya, including Pyrococcus furiosus transcription factor B (PfTFB), human and yeast transcription factor IIS (TFIIS), and Thermococcus celer RNA polymerase II subunit M (TcRPOM). The zinc-ribbon structure of TFIIB, in conjunction with the biochemical analyses, suggests that residues on the beta-sheet are involved in the interaction with RNA pol II/TFIIF, while the zinc-binding site may increase the stability of the beta-sheet.

Intramolecular interaction of yeast TFIIB in transcription control

The general transcription factor TFIIB is a key component in the eukaryotic RNA polymerase II (RNAPII) transcriptional machinery. We have previously shown that a yeast TFIIB mutant (called YR1m4) with four amino acid residues in a species-specific region changed to corresponding human residues affects the expression of genes activated by different activators in vivo. We report here that YR1m4 can interact with several affected activators in vitro. In addition, YR1m4 and other mutants with amino acid alterations within the same region can interact with TATA-binding protein (TBP) and RNAPII normally. However, YR1m4 is defective in supporting activator-independent transcription in assays con-ducted both in vitro and in vivo. We further demonstrate that the interaction between the C-terminal core domain and the N-terminal region is weakened in YR1m4 and other related TFIIB mutants. These results suggest that the intramolecular interaction property of yeast TFIIB plays an important role in transcription regulation in cells.

The role of transcription factor B in transcription initiation and promoter clearance in the archaeon Sulfolobus acidocaldarius

Mechanisms of transcription initiation appear to be remarkably conserved between archaea and eucaryotes. For instance, there is homology between archaeal and eucaryotic basal transcription factors. Also, the archaeal RNA polymerase (RNAP) resembles eucaryotic nuclear RNAPs in subunit composition and at the amino acid sequence level. Here, we examine the role of transcription factor B, the archaeal homologue of eucaryotic transcription factor IIB, in transcription initiation. We show that the N-terminal region of transcription factor B is required for RNAP recruitment. Furthermore, we reveal that mutation of a conserved residue immediately C-terminal of the N-terminal zinc ribbon motif abrogates transcription on certain promoters. Finally, we identify the promoter sequences responsive to this mutation and demonstrate that the effect of the mutation is to block a late stage in transcription initiation, following formation of the promoter open complex.

The zinc ribbon domains of the general transcription factors TFIIB and Brf: conserved functional surfaces but different roles in transcription initiation

The function of the conserved zinc-binding domains in the related Pol II- and Pol III-specific factors TFIIB and Brf was investigated. Three-dimensional structure modeling and mutagenesis studies indicated that for both factors, the functional surface of the zinc ribbon fold consists of a small conserved patch of residues located on one face of the domain comprised mainly of the second and third antiparallel β strands. Previous studies have shown that the TFIIB zinc ribbon is essential for recruitment of Pol II into the preinitiation complex. In contrast, Pol III recruitment assays and in vitro transcription demonstrate that the disruption of the Brf zinc ribbon does not lead to a defect in Pol III recruitment but, rather, a defect in open complex formation. Therefore, the same conserved surface of the zinc ribbon domain has been adapted to serve distinct roles in the Pol II and Pol III transcription machinery.

The conformation of the transcription factor TFIIB modulates the response to transcriptional activators in vivo

The general transcription factor TFIIB plays a crucial role in the assembly of the transcriptional preinitiation complex and has also been proposed as a target of transcriptional activator proteins (reviewed in [1]). TFIIB is composed of two domains which are engaged in an intramolecular interaction that is disrupted upon interaction with the activation domain of the Herpesvirus VP16 protein in vitro [2] [3]. The significance of this event for transcriptional activation is not known, however. The amino-terminal intramolecular interaction domain is the most conserved region of TFIIB and plays a role in transcription start-site selection [4] [5] [6]. In addition, we have shown previously that the integrity of this region is required for transcriptional activation in vivo [4]. Here, we have defined a charge cluster at the amino terminus of TFIIB that is required for transcriptional activation in vivo. We found that this domain determines the affinity of the TFIIB intramolecular interaction and the ability of TFIIB to interact with a transcriptional activation domain, but not with components of the holoenzyme. Our results suggest that the intramolecular interaction in TFIIB regulates transcriptional activation in vivo.

Mutational analysis of yeast TFIIB. A functional relationship between Ssu72 and Sub1/Tsp1 defined by allele-specific interactions with TFIIB

TFIIB is an essential component of the RNA polymerase II core transcriptional machinery. Previous studies have defined TFIIB domains required for interaction with other transcription factors and for basal transcription in vitro. In the study reported here we investigated the TFIIB structural requirements for transcription initiation in vivo. A library of sua7 mutations encoding altered forms of yeast TFIIB was generated by error-prone polymerase chain reaction and screened for conditional growth defects. Twenty-two single amino acid replacements in TFIIB were defined and characterized. These replacements are distributed throughout the protein and occur primarily at phylogenetically conserved positions. Most replacements have little or no effect on the steady-state protein levels, implying that each affects TFIIB function rather than synthesis or stability. In contrast to the initial sua7 mutants, all replacements, with one exception, have no effect on start site selection, indicating that specific TFIIB structural defects affect transcriptional accuracy. This collection of sua7 alleles, including the initial sua7 alleles, was used to investigate the allele specificity of interactions between ssu72 and sub1, both of which were initially identified as either suppressors (SUB1 2mu) or enhancers (sub1Delta, ssu72-1) of sua7 mutations. We show that the interactions of ssu72-1 and sub1Delta with sua7 are allele specific; that the allele specificities of ssu72 and sub1 overlap; and that each of the sua7 alleles that interacts with ssu72 and sub1 affects the accuracy of transcription start site selection. These results demonstrate functional interactions among TFIIB, Ssu72, and Sub1 and suggest that these interactions play a role in the mechanism of start site selection by RNA polymerase II.

Evidence that transcription factor IIB is required for a post-assembly step in transcription initiation

Mutation of glutamate 62 to lysine in yeast transcription factor (TF) IIB (Sua7) causes a cold-sensitive phenotype. This mutant also leads to preferential transcription of downstream start sites on some promoters in vivo. To explore the molecular nature of these phenotypes, the TFIIB E62K mutant was characterized in vitro. The mutant interacts with TATA-binding protein normally. In three different assays, the mutant can also interact with RNA polymerase II and recruit it and the other basal transcription factors to a promoter. Despite the ability to assemble a transcription complex, the TFIIB E62K protein is severely defective in transcription in vitro. Therefore, the role of TFIIB must be more than simply bridging TATA-binding protein and polymerase at the promoter. We propose that the region around Glu-62 in yeast TFIIB plays a role in start site selection, perhaps mediating a conformational change in the polymerase or the DNA during the search for initiation sites. This step may be related to the yeast-specific spacing between TATA elements and start sites since mutations of the corresponding glutamate in mammalian TFIIB do not produce a similar effect.

An interaction between the N-terminal region and the core domain of yeast TFIIB promotes the formation of TATA-binding protein-TFIIB-DNA complexes

The general transcription factor IIB (TFIIB) plays an essential role in transcription of protein-coding genes by eukaryotic RNA polymerase II. We previously identified a yeast TFIIB mutant (R64E) that exhibited increased activity in the formation of stable TATA-binding protein-TFIIB-DNA (DB) complexes in vitro. We report here that the homologous human TFIIB mutant (R53E) also displayed increased activity in DB complex formation in vitro. Biochemical analyses revealed that the increased activity of the R64E mutant in DB complex formation was associated with an altered protease sensitivity of the protein and an enhanced interaction between the N-terminal region and the C-terminal core domain. These results suggest that the intramolecular interaction in yeast TFIIB stabilizes a productive conformation of the protein for the association with promoter-bound TATA-binding protein.

The role of human TFIIB in transcription start site selection in vitro and in vivo

The general transcription factor TFIIB plays a crucial role in selecting the transcription initiation site in yeast. We have analyzed the human homologs of TFIIB mutants that have previously been shown to affect transcription start site selection in the yeast Saccharomyces cerevisiae. Despite the distinct mechanisms of transcription start site selection observed in S. cerevisiae and humans, the role of TFIIB in this process is similar. However, unlike their yeast counterparts, the human mutants do not show a severe defect in supporting either basal transcription or transcription stimulated by an acidic activator in vitro. Transient transfection analysis revealed that, in addition to a role in transcription start site selection, human TFIIB residue Arg-66 performs a critical function in vivo that is bypassed in vitro. Furthermore, although correct transcription start site selection is dependent upon an arginine residue at position 66 in human TFIIB, innate function in vivo is determined by the charge of the residue alone. Our observations raise questions as to the evolutionary conservation of TFIIB and uncover an additional function for TFIIB that is required in vivo but can be bypassed in vitro.

An activation-specific role for transcription factor TFIIB in vivo

A yeast mutant was isolated encoding a single amino acid substitution [serine-53 --> proline (S53P)] in transcription factor TFIIB that impairs activation of the PHO5 gene in response to phosphate starvation. This effect is activation-specific because S53P did not affect the uninduced level of PHO5 expression, yet is not specific to PHO5 because Adr1-mediated activation of the ADH2 gene also was impaired by S53P. Pho4, the principal activator of PHO5, directly interacted with TFIIB in vitro, and this interaction was impaired by the S53P replacement. Furthermore, Pho4 induced a conformational change in TFIIB, detected by enhanced sensitivity to V8 protease. The S53P replacement also impaired activation of a lexA(op)-lacZ reporter by a LexA fusion protein to the activation domain of Adr1, thereby indicating that the transcriptional effect on ADH2 expression is specific to the activation function of Adr1. These results define an activation-specific role for TFIIB in vivo and suggest that certain activators induce a conformational change in TFIIB as part of their mechanism of transcriptional stimulation.

Intermediates in formation and activity of the RNA polymerase II preinitiation complex: holoenzyme recruitment and a postrecruitment role for the TATA box and TFIIB

Assembly and activity of yeast RNA polymerase II (Pol II) preinitiation complexes (PIC) was investigated with an immobilized promoter assay and extracts made from wild-type cells and from cells containing conditional mutations in components of the Pol II machinery. We describe the following findings: (1) In one step, TFIID and TFIIA assemble at the promoter independently of holoenzyme. In another step, holoenzyme is recruited to the promoter. Mutations in the CTD of Pol II, Srb2, Srb4, and Srb5, and two mutations in TFIIB disrupt recruitment of all holoenzyme components tested without affecting TFIID and TFIIA recruitment. These results indicate that the stepwise assembly pathway is blocked after TFIID/TFIIA binding. (2) Both the Gal4-AH and Gal4-VP16 activators stimulate formation of active PICs by increasing the extent of PIC formation. The Gal4-AH activator stimulated PIC formation by enhancing the binding of TFIID and TFIIA, whereas Gal4-VP16 could enhance the recruitment of TFIID, TFIIA, and holoenzyme. (3) Extracts deficient in TFIIA activity showed reduced assembly of all PIC components. These and other results suggest that TFIIA acts at an early step by enhancing the stable recruitment of TFIID. (4) An extract containing the TFIIB mutant E62G, had no defect in PIC formation, but had a severe defect in transcription. Similarly, mutation of the TATA box reduced PIC formation only two- to fourfold, but severely compromised transcription. These results demonstate an involvement of TFIIB and the TATA box in one or more steps after recruitment of factors to the promoter.

Novel cofactors and TFIIA mediate functional core promoter selectivity by the human TAFII150-containing TFIID complex

TATA-binding protein-associated factors (TAFIIs) within TFIID control differential gene transcription through interactions with both activators and core promoter elements. In particular, TAFII150 contributes to initiator-dependent transcription through an unknown mechanism. Here, we address whether TAFIIs within TFIID are sufficient, in conjunction with highly purified general transcription factors (GTFs), for differential core promoter-dependent transcription by RNA polymerase II and whether additional cofactors are required. We identify the human homologue of Drosophila TAFII150 through cognate cDNA cloning and show that it is a tightly associated component of human TFIID. More importantly, we demonstrate that the human TAFII150-containing TFIID complex is not sufficient, in the context of all purified GTFs and RNA polymerase II, to mediate transcription synergism between TATA and initiator elements and initiator-directed transcription from a TAFII-dependent TATA-less promoter. Therefore, TAFII-promoter interactions are not sufficient for the productive core promoter-selective functions of TFIID. Consistent with this finding, we have partially purified novel cofactor activities (TICs) that potentiate the TAFII-mediated synergism between TATA and initiator elements (TIC-1) and TAFII-dependent transcription from TATA-less promoters (TIC-2 and -3). Furthermore, we demonstrate an essential function for TFIIA in TIC- and TAFII-dependent basal transcription from a TATA-less promoter. Our results reveal a parallel between the basal transcription activity of TAFIIs through core promoter elements and TAFII-dependent activator function.

Positive regulation of the human macrophage stimulating protein gene transcription. Identification of a new hepatocyte nuclear factor-4 (HNF-4) binding element and evidence that indicates direct association between NF-Y and HNF-4

We previously reported that the transcription of the human macrophage stimulating protein (MSP) gene was positively regulated by the binding of NF-Y to the CAATT sequence in the promoter region of this gene. Here we confirmed our previous results and further characterized the MSP promoter. Luciferase assay with deletion constructs showed the importance of the region, +32 to +39, for the promoter activity in Hep3B cells. Two nuclear protein-DNA probe (+15 to +40) complexes, C1 and C2, were detected by electrophoretic mobility shift assay. C2 was specific to hepatoma cells and contained hepatocyte nuclear factor-4 (HNF-4). DNase I footprinting with recombinant HNF-4 located another HNF-4-binding site in the distal region, -89 to -54. Mutations in the CAATT or the proximal HNF-4-binding site significantly reduced the promoter activity in Hep3B cells and HNF-4-transfected HeLa cells, whereas mutations in the distal HNF-4-binding site had no effect. The close proximity between the CAATT and the proximal HNF-4-binding site suggested that a direct contact between NF-Y and HNF-4 might be important. Protein-protein interaction between the A-subunit of NF-Y and HNF-4 was detected by a yeast two-hybrid system. The binding of in vitro translated HNF-4 to immobilized NF-YA and in vitro translated NF-YA to immobilized HNF-4 was also detected. These results suggest the binding of HNF-4 to the proximal HNF-4-binding site directs the basal transcription of the MSP gene, and the maximal promoter activity may depend on the direct association between HNF-4 and NF-Y.

The N-terminal region of yeast TFIIB contains two adjacent functional domains involved in stable RNA polymerase II binding and transcription start site selection

The general transcription factor IIB (TFIIB) is required for accurate and efficient transcription of protein-coding genes by RNA polymerase II (RNAPII). To define functional domains in the highly conserved N-terminal region of TFIIB, we have analyzed 14 site-directed substitution mutants of yeast TFIIB for their ability to support cell viability, transcription in vitro, accurate start site selection in vitro and in vivo, and to form stable complexes with purified RNAPII in vitro. Mutations impairing the formation of stable TFIIB.RNAPII complexes mapped to the zinc ribbon fold, whereas mutations conferring downstream shifts in transcription start site selection were identified at multiple positions within a highly conserved homology block adjacent and C-terminal to the zinc ribbon. These results demonstrate that the N-terminal region of yeast TFIIB contains two separable and adjacent functional domains involved in stable RNAPII binding and transcription start site selection, suggesting that downstream shifts in transcription start site selection do not result from impairment of stable TFIIB.RNAPII binding. We discuss models for yeast start site selection in which TFIIB may affect the ability of preinitiation complexes to interact with downstream DNA or to affect start site recognition by a scanning polymerase.

Molecular genetics of the RNA polymerase II general transcriptional machinery

Transcription initiation by RNA polymerase II (RNA pol II) requires interaction between cis-acting promoter elements and trans-acting factors. The eukaryotic promoter consists of core elements, which include the TATA box and other DNA sequences that define transcription start sites, and regulatory elements, which either enhance or repress transcription in a gene-specific manner. The core promoter is the site for assembly of the transcription preinitiation complex, which includes RNA pol II and the general transcription fctors TBP, TFIIB, TFIIE, TFIIF, and TFIIH. Regulatory elements bind gene-specific factors, which affect the rate of transcription by interacting, either directly or indirectly, with components of the general transcriptional machinery. A third class of transcription factors, termed coactivators, is not required for basal transcription in vitro but often mediates activation by a broad spectrum of activators. Accordingly, coactivators are neither gene-specific nor general transcription factors, although gene-specific coactivators have been described in metazoan systems. Transcriptional repressors include both gene-specific and general factors. Similar to coactivators, general transcriptional repressors affect the expression of a broad spectrum of genes yet do not repress all genes. General repressors either act through the core transcriptional machinery or are histone related and presumably affect chromatin function. This review focuses on the global effectors of RNA polymerase II transcription in yeast, including the general transcription factors, the coactivators, and the general repressors. Emphasis is placed on the role that yeast genetics has played in identifying these factors and their associated functions.

[Activation of transcription in eukaryotic cells: interactions between transcription factors and components of the basal transcriptional mechanism]

Regulation of transcription in eucaryotes is achieved by two classes of transcription factors, GTFs (general transcription factors), which are components of the basal machinery, and sequence- and tissue-specific transcription factors. In this review, recent insights into the structure and function of components from the basal transcriptional machinery are discussed. The mechanisms of transcriptional activation involving direct interactions between trans-activators and the basal machinery are also presented.

Hepatitis B virus X protein is a transcriptional modulator that communicates with transcription factor IIB and the RNA polymerase II subunit 5

Hepatitis B virus X protein (HBx) transactivates viral and cellular genes through a wide variety of cis-elements. However, the mechanism is still obscure. Our finding that HBx directly interacts with RNA polymerase II subunit 5 (RPB5), a common subunit of RNA polymerases, implies that HBx directly modulates the function of RNA polymerase (Cheong, J. H., Yi, M., Lin, Y., and Murakami, S. (1995) EMBO J. 14, 142-150). In this context, we examined the possibility that HBx and RPB5 interact with other general transcription factors. HBx and RPB5 specifically bound to transcription factor IIB (TFIIB) in vitro, both of which were detected by either far-Western blotting or the glutathione S-transferase-resin pull-down assay. Delineation of the binding regions of these three proteins revealed that HBx, RPB5, and TFIIB each has two binding regions for the other two proteins. Co-immunoprecipitation using HepG2 cell lysates that express HBx demonstrated trimeric interaction in vivo. Some HBx substitution mutants, which had severely impaired transacting activity, exhibited reduced binding affinity with either TFIIB or RPB5 in a mutually exclusive manner, suggesting that HBx transactivation requires the interactions of both RPB5 and TFIIB. These results indicated that HBx is a novel virus modulator that facilitates transcriptional initiation by stabilizing the association between RNA polymerase and TFIIB through communication with RPB5 and TFIIB.

Eukaryotic transcription factor-DNA complexes

Eukaryotes have three distinct RNA polymerases that catalyze transcription of nuclear genes. RNA polymerase II is responsible for transcribing nuclear genes encoding the messenger RNAs and several small nuclear RNAs. Like RNA polymerases I and III, polymerase II cannot recognize its target promoter directly and initiate transcription without accessory factors. Instead, this large multisubunit enzyme relies on general transcription factors and transcriptional activators and coactivators to regulate transcription from class II promoters. X-ray crystallography and nuclear magnetic resonance spectroscopy have been used to study complexes of general transcription factors and transcriptional activators with their specific DNA targets. This work has provided important structural insights into transcription initiation by polymerase II and the more general problem of DNA sequence recognition.

Mutations in an Abf1p binding site in the promoter of yeast RPO26 shift the transcription start sites and reduce the level of RPO26 mRNA

A binding site for the transcription factor Abf1p was identified as an important promoter element of the gene that encodes Rpo26, a subunit common to all three yeast nuclear RNA polymerases (RNAP). Mutations in the Abf1p binding site were identified among a pool of rpo26 mutant alleles that confer synthetic lethality in combination with a temperature-sensitive mutation (rpo21-4) in the gene that encodes the largest subunit of RNAPII (Rpo21p). In the presence of the wild-type allele of RPO21 these rpo26 promoter mutations confer a cold-sensitive growth defect. Electrophoretic mobility-shift assays using purified Abf1p demonstrated that Abf1p binds to the RPO26 promoter and that the promoter mutations abolish this binding in vitro. Quantitation of the amount of RPO26 mRNA showed that mutations in the Abf1p binding site reduce the expression of RPO26 by approximately 60%. Mutations that affect Abf1p binding also result in a shift of the RPO26 transcriptional start sites to positions further upstream than normal. These results suggest that binding of the Abf1p transcription factor to the RPO26 promoter is important not only in establishing the level of transcription for this gene, but also in positioning the initiation sites of transcription.

A minimal set of RNA polymerase II transcription protein interactions

All pairwise interactions of RNA polymerase II and general transcription factors (TF) IIB, E, F, and H have been quantitated by surface plasmon resonance with the use of a Ni2+ chelate on the sensor surface where necessary to attain higher sensitivity. Only 4 of 10 possible interactions were found above the detection limit: TFIIB, -E, and -F binding to RNA polymerase II and TFIIE binding to TFIIH. These four interactions constitute a minimal set for the formation of a transcription initiation complex and may represent the primary interactions involved in assembly of the complex. Point mutations in TFIIB that alter the location of transcription start sites in vivo markedly diminished the affinity of TFIIB binding to RNA polymerase II. Protein blotting revealed an interaction between the largest subunit of TFIIE and third largest subunit of TFIIH, which may be responsible for TFIIE binding to TFIIH.

Two-dimensional crystallography of TFIIB- and IIE-RNA polymerase II complexes: implications for start site selection and initiation complex formation

SUMMARY

Transcription factors IIB (TFIIB) and IIE (TFIIE) bound to RNA polymerase II have been revealed by electron crystallography in projection at 15.7 A resolution. The results lead to simple hypotheses for the roles of these factors in the initiation of transcription. TFIIB is suggested to define the distance from TATA box to transcription start site by bringing TATA DNA in contact with polymerase at that distance from the active center of the enzyme. TFIIE is suggested to participate in a key conformational switch occurring at the active center upon polymerase-DNA interaction.

RNA polymerase II-associated protein (RAP) 74 binds transcription factor (TF) IIB and blocks TFIIB-RAP30 binding

A set of deletion mutants of human RNA polymerase II-associated protein (RAP) 30, the small subunit of transcription factor IIF (TFIIF; RAP30/74), was constructed to map functional domains. Mutants were tested for accurate transcriptional activity, RAP74 binding, and TFIIB binding. Transcription assays indicate the importance of both N- and C-terminal sequences for RAP30 function. RAP74 binds to the N-terminal region of RAP30 between amino acids 1 and 98. TFIIB binds to an overlapping region of RAP30, localized to amino acids 1-176 (amino acids 27-152 comprise a minimal binding region). The C-terminal region of RAP74 (amino acids 358-517) binds directly and independently to TFIIB. Interestingly, RAP74 blocks TFIIB-RAP30 binding, both by binding TFIIB and by binding RAP30. When the TFIIF complex is intact, therefore, TFIIB-TFIIF contact is maintained through RAP74. If the TFIIB-RAP30 interaction is physiologically important, the TFIIF complex must dissociate within some transcription complexes.

The N-terminal domain of TFIIB from Pyrococcus furiosus forms a zinc ribbon

The three-dimensional structure of the N-terminal domain of an archaeal TFIIB, which has high sequence homology with eucaryal analogues, is strikingly similar to that of the C-terminal zinc ribbon of the eucaryal transcription elongation factor TFIIB.

Crystal structure of a TFIIB-TBP-TATA-element ternary complex

The crystal structure of the transcription factor IIB (TFIIB)/TATA box-binding protein (TBP)/TATA-element ternary complex is described at 2.7 A resolution. Core TFIIB resembles cyclin A, and recognizes the preformed TBP-DNA complex through protein-protein and protein-DNA interactions. The amino-terminal domain of core TFIIB forms the downstream surface of the ternary complex, where it could fix the transcription start site. The remaining surfaces of TBP and the TFIIB can interact with TBP-associated factors, other class II initiation factors, and transcriptional activators and coactivators.

Characterization of physical interactions of the putative transcriptional adaptor, ADA2, with acidic activation domains and TATA-binding protein

RNA polymerase II transcription requires functional interactions between activator proteins bound to upstream DNA sites and general factors bound to the core promoter. Accessory transcription factors, such as adaptors and coactivators, have important, but still unclear, roles in the activation process. We tested physical interactions of the putative adaptor ADA2 with activation domains derived from acidic activator proteins and with certain general transcription factors. ADA2 associated with the herpesvirus VP16 and yeast GCN4 activation domains but not with the activation domain of yeast HAP4, which previously was shown to be independent of ADA2 function in vivo and in vitro. Furthermore, the amino terminus of ADA2 directly interacted with the VP16 activation domain, suggesting that ADA2 provides determinants for interaction between activation domains and the adaptor complex. Both TATA-binding protein (TBP) and TFIIB have previously been shown to interact directly with the VP16 activation domain in vitro (Stringer, K. F., Ingles, C. J., and Greenblatt, J. (1990) Nature 345, 783-786; Lin, Y. S., Ha, I., Maldonado, E., Reinberg, D., and Green, M. R. (1991) Nature 353, 569-571). Interestingly, when binding was tested between VP16 and these general factors in yeast nuclear extracts, both factors interacted with VP16, but only the TBP/VP16 association was dependent on ADA2. In addition, ADA2 physically associated with TBP, but not with TFIIB. These results suggest that the role of ADA2 in transcriptional activation is to promote physical interaction between activation domains and TBP.