Isolation of two genes that encode subunits of the yeast transcription factor IIA

[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.

Protease footprinting analysis of ternary complex formation by human TFIIA

Transcription factor (TF) IIA performs two important regulatory functions during RNA polymerase II transcription: it is required for efficient binding of TFIID to a core promoter and it mediates the effects of upstream activators, both through direct interaction with the TATA box binding protein (TBP). To begin studying how TFIIA mediates these effects, we used a highly sensitive protease footprinting methodology to identify surfaces of human TFIIA participating in TFIIA x TBP x TATA ternary complex formation. Chymotrypsin and proteinase K cleavage patterns of TFIIA bearing a 32P-end-labeled gamma subunit revealed that amino acids 59-73 were protected from cleavage both in the context of an immobilized ternary complex and in a binary complex with TBP alone. In contrast, amino acids 341-367 in the beta portion of a 32P-labeled alpha-beta subunit were protected in the ternary but not in the binary complex, implying that those residues interact with promoter DNA. The regions of human TFIIA identified by protease footprinting are homologous to and encompass the yeast TFIIA residues that contact TBP and DNA in the recently solved crystal structure of the yeast ternary complex. The conservation of the regions and residues mediating complex formation implies that yeast and human TFIIA employ the same mechanism to stabilize the binding of TFIID to a core promoter.

The transcriptional apparatus required for mRNA encoding genes in the yeast Saccharomyces cerevisiae emerges from a jigsaw puzzle of transcription factors

The number of identified yeast factors involved in transcription has dramatically increased in recent years and the understanding of the interplay between the different factors has become more and more puzzling. Transcription initiation at the core promoter of mRNA encoding genes consisting of upstream, TATA and initiator elements requires an approximately ribosome-sized complex of more than 50 polypeptides. The recent identification and isolation of an RNA polymerase holoenzyme which seems to be preassembled before interacting with a promoter allowed a better understanding of the roles, assignments and interplays of the various constituents of the basal transcription machinery. Recruitment of this complex to the promoter is achieved by numerous interactions with a variety of DNA-bound proteins. These interactions can be direct or mediated by additional adaptor proteins. Other proteins negatively affect transcription by interrupting the recruitment process through protein-protein or protein-DNA interactions. Some basic features of cis-acting elements, the transcriptional apparatus and various trans-acting factors involved in the initiation of mRNA synthesis in yeast are summarized.

Characterization of the basal inhibitor of class II transcription NC2 from Saccharomyces cerevisiae

Human NC2 utilizes a unique mechanism of repression of transcription by associating with TBP and inhibition of preinitiation complex formation. Here we have cloned two genes from Saccharomyces cerevisiae and functionally characterized them as yeast NC2. We show that yeast NC2 binds to TBP as a heterodimer and represses RNA polymerase II transcription during assembly of the preinitiation complex. Yeast NC2 is highly homologous to its human counterpart within histone fold domains. C-Terminal regions previously discussed to be important for repression in man are in part not conserved. The human alpha but not the beta subunit efficiently heterodimerizes and represses transcription in combination with the corresponding yeast subunit. Yeast and human NC2 inhibit transcription in the presence of yeast and human TBP. However, repression is optimal within one species. The N-terminus of human TBP supports repression of transcription by human but not by yeast NC2.

High-resolution mapping of nucleoprotein complexes by site-specific protein-DNA photocrosslinking: organization of the human TBP-TFIIA-TFIIB-DNA quaternary complex

We have used a novel site-specific protein-DNA photocrosslinking procedure to define the positions of polypeptide chains relative to promoter DNA in binary, ternary, and quaternary complexes containing human TATA-binding protein, human or yeast transcription factor IIA (TFIIA), human transcription factor IIB (TFIIB), and promoter DNA. The results indicate that TFIIA and TFIIB make more extensive interactions with promoter DNA than previously anticipated. TATA-binding protein, TFIIA, and TFIIB surround promoter DNA for two turns of DNA helix and thus may form a "cylindrical clamp" effectively topologically linked to promoter DNA. Our results have implications for the energetics, DNA-sequence-specificity, and pathway of assembly of eukaryotic transcription complexes.

Radical mutations reveal TATA-box binding protein surfaces required for activated transcription in vivo

Regions on the surface of human TATA-box binding protein (TBP) required for activated transcription in vivo were defined by construction of a library of 89 surface residue mutants with radical substitutions that were assayed for their ability to support activated transcription in vivo, basal transcription in vitro, and TFIIA and TFIIB binding in vitro. Four epitopes were identified in which substitutions in two to four neighboring surface residues greatly inhibited activated transcription in vivo. One epitope in which substitutions inhibited both basal and activated transcription (E284, L287) is the interface between TBP and TFIIB. Another (A184, N189, E191, R205) is the recently determined interface between TBP and TFIIA. Mutations in residues in this TFIIA interface greatly inhibit activated, but not basal transcription, demonstrating a requirement for the TFIIA-TBP interaction for activated transcription in vivo in mammalian cells. The remaining two activation epitopes (TBP helix 2 residues R231, R235, R239, plus F250; and G175, C176, P247) are probably interfaces with other proteins required for activated transcription. The library of mutants responded virtually identically to two different types of activators, GL4-E1A and GAL4-VP16, indicating that transcriptional activation by different classes of activators requires common interactions with TBP.

A new class of activation-defective TATA-binding protein mutants: evidence for two steps of transcriptional activation in vivo

Using a genetic screen, we isolated four TATA-binding protein (TBP) mutants that are specifically defective in vivo for the response to acidic activators. In contrast to previously described activation-defective TBP mutants, these TBP derivatives are not specifically defective for interactions with TATA elements or TFIIA. Three of these derivatives interact normally with a TATA element, TFIIA, TFIIB, or an acidic activation domain; presumably, they affect another protein-protein interaction important for transcriptional activation. The remaining derivative (with F-237 replaced by D) binds a TATA element with wild-type affinity, but the TBP-TATA complex has an altered electrophoretic mobility and interacts poorly with TFIIA and TFIIB; this suggests that the conformation of the TBP-TATA element complex plays a role in transcriptional activation. To determine the step at which the TBP derivatives were unable to activate transcription, we utilized an artificial recruitment assay in which TBP is targeted to the promoter via fusion to the LexA DNA-binding domain. Consistent with previous evidence that acidic activators can increase recruitment of TBP to the promoter in vivo, the activation defect of some of these TBP derivatives can be corrected by artificial recruitment. In contrast, the activation defect of the other TBP derivatives is not bypassed by artificial recruitment. Thus, these TBP mutants define two steps in the process of transcriptional stimulation by acidic activators: efficient recruitment to the TATA element and a postrecruitment interaction with a component(s) of the initiation complex.

Crystal structure of the yeast TFIIA/TBP/DNA complex

The crystal structure of the yeast TFIIA/TBP/TATA promoter complex was solved to 3 angstrom resolution by double-edge multiple wavelength anomalous diffraction from two different species of anomalous scattering elements in the same crystal. The large and small subunits of TFIIA associate intimately to form both domains of a two-domain folding pattern. TFIIA binds as a heterodimer to the side of the TBP/TATA complex opposite to the side that binds TFIIB and does not alter the TBP/DNA interaction. The six-stranded beta-sandwich domain interacts with the amino-terminal end of TBP through a stereospecific parallel beta-strand interface and with the backbone of the TATA box and the 5'-flanking B-DNA segment. The four-helix-bundle domain projects away from the TBP/TATA complex, thereby presenting a substantial surface for further protein-protein interactions.

Transcription factor IIA mutations show activator-specific defects and reveal a IIA function distinct from stimulation of TBP-DNA binding

The general transcription factor IIA (TFIIA) binds to the TATA binding protein (TBP) and mediates transcriptional activation by distinct classes of activators. To elucidate the function of TFIIA in transcriptional activation, point mutants were created in the human TFIIA-gamma subunit at positions conserved with the yeast homologue. We have identified a class of TFIIA mutants that stimulate TBP-DNA binding (T-A complex) but fail to support transcriptional activation by several different activators, suggesting that these mutants are defective in their ability to facilitate an activation step subsequent to TBP promoter binding. Point mutations of the hydrophobic core of conserved residues from 65 to 74 resulted in various activation-defective phenotypes. These residues were found to be important for TFIIA gamma-gamma interactions, suggesting that gamma-gamma interactions are critical for TFIIA function as a coactivator. A subset of these TFIIA-gamma mutations disrupted transcriptional activation by all activators tested, except for the Epstein-Barr virus-encoded Zta protein. The gamma Y65F, gamma W72A, and gamma W72F mutants mediate Zta activation, but not GAL4-AH, AP-1, GAL4-CTF, or GAL4-VP16 activation. The gamma W72A mutant failed to stimulate TFIID-DNA binding (D-A complex) but was able to form a complex with TFIID and DNA in the presence of Zta (Z-D-A complex). Thus, the ability of Zta to activate transcription with gamma W72A appears to result from a unique ability to form the stable Z-D-A complex with this mutant. Our results show that different activators utilize the general factor TFIIA in unique ways and that TFIIA contributes transcription activation functions in addition to the facilitation of TBP-DNA binding.

Crystal structure of a yeast TFIIA/TBP/DNA complex

The X-ray crystal structure of the transcription factor IIA (TFIIA) in complex with the TATA-box-binding protein (TBP) and TATA-element DNA is presented at 2.5 A resolution. TFIIA is composed of a beta-barrel and a four-helix bundle motif that together have a boot-like appearance. The beta-barrel extends the TBP beta-sheet and bridges over the DNA major groove immediately upstream of the TATA box. The four-helix bundle contributes substantially to the surface of the complex available for interaction with additional transcription factors.

RNA polymerase II holoenzyme contains SWI/SNF regulators involved in chromatin remodeling

The RNA polymerase II holoenzyme contains RNA polymerase II, a subset of general transcription factors and SRB regulatory proteins. We report here that SWI and SNF gene products, previously identified as global gene regulators whose functions include remodeling chromatin, are also integral components of the yeast RNA polymerase II holoenzyme. The SWI/SNF proteins are components of the SRB complex, also known as the mediator, which is tightly associated with the RNA polymerase II C-terminal repeat domain. The SWI/SNF components provide the holoenzyme with the capacity to disrupt nucleosomal DNA and thus facilitate stable binding of various components of the transcription initiation complex at promoters.

Drosophila TFIIA-S is up-regulated and required during Ras-mediated photoreceptor determination

Photoreceptor induction in the developing Drosophila eye is triggered by the activation of the Ras pathway. Subsequently, the Ras-mediated activation of site-specific transcription factors leads to the expression of putative "effector" genes. The coactivator function of the basal transcription factor TFIIA has been shown previously to enhance the trans-activation potential of site-specific transcription factors in vitro. Here, we show that the expression of the small subunit of TFIIA (dTFIIA-S) is specifically up-regulated in a transient manner during Ras-mediated photoreceptor induction. Furthermore, although null mutations in dTFIIA-S are cell lethal, a hypomorphic dTFIIA-S allele demonstrates an increased requirement for this factor during photoreceptor development. In addition, the cone cell to R7 photoreceptor transformation caused by ectopic activation of the Ras pathway during eye development is suppressed by the removal of one functional copy of the dTFIIA-S locus revealing the sensitivity of this process to reductions in dTFIIA-S activity. These results are the first in vivo evidence for the coactivator function in transcriptional enhancement proposed for TFIIA.

The amino-terminal tails of the core histones and the translational position of the TATA box determine TBP/TFIIA association with nucleosomal DNA

We establish that the TATA binding protein (TBP) in the presence of TFIIA recognizes the TATA box in nucleosomal DNA dependent on the dissociation of the amino-terminal tails of the core histones from the nucleosome and the position of the TATA box within the nucleosome. We examine TBP/TFIIA access to the TATA box with this sequence placed in four distinct rotational frames with reference to the histone surface and at three distinct translational positions at the edge, side and dyad axis of the nucleosome. Under our experimental conditions, we find that the preferential translational position at which TBP/TFIIA can bind the TATA box is within linker DNA at the edge of the nucleosome and that binding is facilitated if contacts made by the amino-terminal tails of the histones with nucleosomal DNA are eliminated. TBP/TFIIA binding to DNA at the edge of the nucleosome occurs with the TATA box in all four rotational positions. This is indicative of TBP/TFIIA association directing the dissociation of the TATA box from the surface of the histone octamer.

A class of activation domains interacts directly with TFIIA and stimulates TFIIA-TFIID-promoter complex assembly

TFIIA is a general transcription factor that interacts with the TFIID-promoter complex required for transcription initiation by RNA polymerase II. Two lines of evidence suggest that TFIIA is directly involved in the mechanism by which some activators stimulate transcription. First, binding of TFIIA to a TFIID-promoter complex is a rate-limiting step that is enhanced by transcriptional activators GAL4-AH and Zta. Second, recombinant TFIIA greatly enhances activator-dependent transcription. In this study, we found that the activation domains of Zta and VP16 bind directly to TFIIA. Both Zta and VP16 stimulated rapid assembly of a stable TFIID-TFIIA complex on promoter DNA. Analysis of deletion derivatives of the VP16 activation domain indicated that the ability to bind to TFIIA correlates with the ability to enhance TFIID-TFIIA-promoter ternary complex assembly. Thus, we propose that a class of activators stimulate transcription initiation through direct interactions with both TFIIA and TFIID, which stimulate the assembly of an activated TFIIA-TFIID-promoter complex.

The complete sequence of a 9000 bp fragment of the right arm of Saccharomyces cerevisiae chromosome VII contains four previously unknown open reading frames

We report the sequence of a 9000 bp fragment from the right arm of Saccharomyces cerevisiae chromosome VII. Analysis of the sequence revealed four complete previously unknown open reading frames, which were named G7587, G7589, G7591 and G7594 following standard rules for provisional nomenclature. Outstanding features of some of these proteins were the homology of the putative protein coded by G7589 with proteins involved in transcription regulation and the transmembrane domains predicted in the putative protein coded by G7591.

The TBP-TFIIA interaction in the response to acidic activators in vivo

A yeast TBP mutant (N2-1) is described here that is defective specifically in responding to acidic activators in vivo. N2-1 does not support activation by Gal4, Ace1, and Gcn4, but appears unaffected for constitutive transcription, repression by the Cyc8-Tup1 and Not complexes, and transcription by polymerase I (Pol) and Pol III. In vitro, N2-1 fails to interact with TFIIA, but it associates normally with a TATA element, an acidic activation domain, and TFIIB. Fusion of the small subunit of TFIIA to N2-1 restores activation function in vivo. Thus, an efficient interaction between TBP and TFIIA is required for transcriptional activation in vivo.

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.

News on initiation and elongation of transcription by RNA polymerase II

Transcription by RNA polymerase II is a complex process that requires additional factors to initiate transcription at the promoters. New developments in the past year have furthered our understanding of the functions of the transcription factors and provided more insights into the mechanisms involved in the regulation of initiation and elongation of transcription. One of the most significant advances of the past year was the discovery of the involvement of the general transcription factor TFIIH in DNA excision repair. Surprisingly, studies aimed at identifying the kinase activity within TFIIH responsible for phosphorylating the carboxy-terminal domain of RNA polymerase II revealed it to be the MO15/Cdk7 kinase and its partner, cyclin H. These exciting observations suggest a paradigm for linking transcription, DNA excision repair and cell cycle progression through one pivotal factor.

Human general transcription factor TFIIA: characterization of a cDNA encoding the small subunit and requirement for basal and activated transcription

The human general transcription factor TFIIA is one of several factors involved in specific transcription by RNA polymerase II, possibly by regulating the activity of the TATA-binding subunit (TBP) of TFIID. TFIIA purified from HeLa extracts consists of 35-, 19-, and 12-kDa subunits. Here we describe the isolation of a cDNA clone (hTFIIA gamma) encoding the 12-kDa subunit. Using expression constructs derived from hTFIIA gamma and TFIIA alpha/beta (which encodes a 55-kDa precursor to the alpha and beta subunits of natural TFIIA), we have constructed a synthetic TFIIA with a polypeptide composition similar to that of natural TFIIA. The recombinant complex supports the formation of a DNA-TBP-TFIIA complex and mediates both basal and Gal4-VP16-activated transcription by RNA polymerase II in TFIIA-depleted nuclear extracts. In contrast, TFIIA has no effect on tRNA and 5S RNA transcription by RNA polymerase III in this system. We also present evidence that both the p55 and p12 recombinant subunits interact with TBP and that the basic region of TBP is critical for the TFIIA-dependent function of TBP in nuclear extracts.

Analysis of the yeast transcription factor TFIIA: distinct functional regions and a polymerase II-specific role in basal and activated transcription

To probe the structure and function of the Saccharomyces cerevisiae general transcription factor TFIIA, we have systematically mutagenized the genes encoding both subunits and analyzed the effects of the mutations both in vivo and in vitro. We found that the central nonconserved region of the large subunit is not essential for function and likely acts as a spacer between the conserved N- and C-terminal regions. Deletion mutagenesis of the large subunit defined a region which is required for TATA binding protein (TBP) interaction. Alanine scanning mutagenesis defined a cluster of four basic residues which are likely required for interaction with DNA in the TBP-DNA complex. Much of the conserved regions of both subunits is required for subunit association, suggesting that these conserved regions fold into compact domains which extensively interact. In vitro transcription performed with extracts from yeast strains with mutations in either the large or the small TFIIA subunit demonstrated that TFIIA stimulates both basal and activated polymerase II (Pol II) transcription. The TFIIA-depleted extracts have normal Pol I and Pol III transcription activity, showing that TFIIA is a Pol II-specific factor. In vivo depletion of TFIIA activity reduced transcription from four different Pol II promoters. Finally, alanine scanning mutagenesis of TFIIA's small subunit has identified at least one mutation which is defective in transcription but which is not defective in subunit association or binding to TBP or TBP-DNA complexes.

Identification of functional targets of the Zta transcriptional activator by formation of stable preinitiation complex intermediates

Transcriptional activator proteins stimulate the formation of a preinitiation complex that may be distinct from a basal-level transcription complex in its composition and stability. Components of the general transcription factors that form activator-dependent stable intermediates were determined by the use of Sarkosyl and oligonucleotide challenge experiments. High-level transcriptional activation by the Epstein-Barr virus-encoded Zta protein required an activity in the TFIID fraction that is distinct from the TATA-binding protein (TBP) and the TBP-associated factors. This additional activity copurifies with and is likely to be identical to the previously defined coactivator, USA (M. Meisterernst, A. L. Roy, H. M. Lieu, and R. G. Roeder, Cell 66:981-994, 1991). The formation of a stable preinitiation complex intermediate resistant to Sarkosyl required the preincubation of the promoter DNA with Zta, holo-TFIID (TBP and TBP-associated factors), TFIIB, TFIIA, and the coactivator USA. The formation of a Zta response element-resistant preinitiation complex required the preincubation of promoter DNA with Zta, holo-TFIID, TFIIB, and TFIIA. Agarose gel electrophoretic mobility shift showed that a preformed Zta-holo-TFIID-TFIIA complex was resistant to Sarkosyl and to Zta response element oligonucleotide challenge. DNase I footprinting suggests that only Zta, holo-TFIID, and TFIIA make significant contacts with the promoter DNA. These results provide functional and physical evidence that the Zta transcriptional activator influences at least two distinct steps in preinitiation complex assembly, the formation of the stable holo-TFIID-TFIIA-promoter complex and the subsequent binding of TFIIB and a USA-like coactivator.

Identification of functional targets of the Zta transcriptional activator by formation of stable preinitiation complex intermediates

Transcriptional activator proteins stimulate the formation of a preinitiation complex that may be distinct from a basal-level transcription complex in its composition and stability. Components of the general transcription factors that form activator-dependent stable intermediates were determined by the use of Sarkosyl and oligonucleotide challenge experiments. High-level transcriptional activation by the Epstein-Barr virus-encoded Zta protein required an activity in the TFIID fraction that is distinct from the TATA-binding protein (TBP) and the TBP-associated factors. This additional activity copurifies with and is likely to be identical to the previously defined coactivator, USA (M. Meisterernst, A. L. Roy, H. M. Lieu, and R. G. Roeder, Cell 66:981-994, 1991). The formation of a stable preinitiation complex intermediate resistant to Sarkosyl required the preincubation of the promoter DNA with Zta, holo-TFIID (TBP and TBP-associated factors), TFIIB, TFIIA, and the coactivator USA. The formation of a Zta response element-resistant preinitiation complex required the preincubation of promoter DNA with Zta, holo-TFIID, TFIIB, and TFIIA. Agarose gel electrophoretic mobility shift showed that a preformed Zta-holo-TFIID-TFIIA complex was resistant to Sarkosyl and to Zta response element oligonucleotide challenge. DNase I footprinting suggests that only Zta, holo-TFIID, and TFIIA make significant contacts with the promoter DNA. These results provide functional and physical evidence that the Zta transcriptional activator influences at least two distinct steps in preinitiation complex assembly, the formation of the stable holo-TFIID-TFIIA-promoter complex and the subsequent binding of TFIIB and a USA-like coactivator.

Drosophila TFIIA directs cooperative DNA binding with TBP and mediates transcriptional activation

Drosophila transcription factor IIA (TFIIA) is composed of three subunits (30, 20, and 14 kD) that function during initiation of transcription. We reported previously the characterization of cDNAs that encode a precursor (dTFIIA-L) of the Drosophila TFIIA 30- and 20-kD subunits. In the absence of the smallest subunit, dTFIIA-S (14 kD), the unprocessed large subunit failed to exhibit any detectable promoter binding or transcriptional activity. Here, we report the molecular cloning and expression of dTFIIA-S, which has allowed the assembly of holo-dTFIIA (dTFIIA-L/S). Subunit interaction studies indicate that dTFIIA-S binds to an amino-terminal domain of dTFIIA-L, which likely corresponds to the endogenous 30-kD processed species. In addition, both dTFIIA-S and the carboxy-terminal domain of dTFIIA-L, which corresponds to the 20-kD species, independently interact weakly with the TATA-binding protein (TBP). In contrast, the holo-dTFIIA (L/S) binds TBP with high affinity. The dTFIIA-L/S complex also binds cooperatively with TBP to TATA box DNA sequences, generating an extended DNase footprint pattern. The reconstituted holo-dTFIIA is able to stimulate basal transcription of several core promoter templates. Interestingly, dTFIIA-L/S is also able to significantly enhance transcriptional activation by upstream transcription factors including Sp1, VP16, and NTF-1. These results suggest that dTFIIA is a multifunctional transcription factor capable of influencing DNA binding as well as interactions with the basal machinery, thereby enhancing activator-dependent transcription.

Molecular cloning of the small (gamma) subunit of human TFIIA reveals functions critical for activated transcription

TFIIA is thought to play an important role in transcriptional regulation in higher eukaryotes, but its precise function is unclear. A human cDNA encoding a protein with 45% identity to the small subunit of yeast TFIIA has been isolated. TFIIA activity could be reconstituted by the mixing of recombinant large (alpha beta) and small (gamma) subunits. TFIIA-depleted HeLa nuclear extracts were used to demonstrate that TFIIA is essential for basal and activated transcription by several distinct classes of activators. Recombinant TFIIA functioned in transcriptional activation whether expressed as a dimer (alpha beta+gamma) or as a trimer (alpha+beta+gamma), which closely resembles the native form. Yeast TFIIA also functioned in transcriptional activation, and the human gamma subunit was functionally interchangeable with TOA2, its yeast homolog. Recombinant TFIIA mediated the stimulation of TFIID binding to the TATA region and downstream promoter sequences by the Zta transcriptional activator. Significantly, we found that TFIIA bound directly to Zta in an activation domain-dependent manner. One consequence of the TFIIA-mediated interaction between Zta and TFIID was the formation of a promoter-bound complex resistant to TATA oligonucleotide competition. These results demonstrate that TFIIA is an evolutionarily conserved general factor critical for activator-regulated transcription.

2.1 A resolution refined structure of a TATA box-binding protein (TBP)

The three-dimensional structure of a TATA box-binding protein (TBP2) from Arabidopsis thaliana has been refined at 2.1 A resolution. TBPs are general eukaryotic transcription factors that participate in initiation of RNA synthesis by all three eukaryotic RNA polymerases. The carboxy-terminal portion of TBP is a unique DNA-binding motif/protein fold, adopting a highly symmetric alpha/beta structure that resembles a molecular saddle with two stirrup-like loops. A ten-stranded, antiparallel beta-sheet provides a concave surface for recognizing class II nuclear gene promoters, while the four amphipathic alpha-helices on the convex surface are available for interaction with other transcription factors. The myriad interactions of TBP2 with components of the transcription machinery are discussed.

Mot1, a global repressor of RNA polymerase II transcription, inhibits TBP binding to DNA by an ATP-dependent mechanism

Basal transcription of many genes in yeast is repressed by Mot1, an essential protein which is a member of the Snf2/Swi2 family of conserved nuclear factors. ADI is an ATP-dependent inhibitor of TATA-binding protein (TBP) binding to DNA that inhibits transcription in vitro. Here we demonstrate that ADI is encoded by the MOT1 gene. Mutation of MOT1 abolishes ADI activity and derepresses basal transcription in vitro and in vivo. Recombinant Mot1 removes TBP from DNA and Mot1 contains an ATPase activity which is essential for its function. Genetic interactions between Mot1 and TBP indicate that their functions are interlinked in vivo. These results provide a general model for understanding the mechanism of action of a large family of nuclear factors involved in processes such as transcription and DNA repair.

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.

A mechanism for TAFs in transcriptional activation: activation domain enhancement of TFIID-TFIIA--promoter DNA complex formation

TATA-binding protein (TBP)-associated factors (TAFs) in TFIID are required for activator proteins to stimulate transcription, but the mechanism by which TAFs function is poorly understood. To study how TAFs participate in transcriptional activation by the Epstein-Barr virus activator Zta, we used agarose gel electrophoresis and DNase I footprinting to compare transcription complex assembly in reactions with either TFIID or TBP in the presence and absence of wild-type Zta or a deletion of Zta lacking its activation domain. A stable complex of promoter DNA with Zta, TFIIA, and TFIID rapidly formed on a template with Zta-binding sites. Zta stimulation of stable complex formation required TAFs as well as the Zta activation domain and TFIIA. The Zta activation domain also induced a TAF-dependent DNA-protein interaction near and downstream of the transcription star site. Stable complexes formed within 1 min supported activated transcription when RNA polymerase II and the remaining general transcription factors were subsequently added. This rapid assembly of a stable Zta-TFIIA-TFIID-promoter complex is probably a significant component of the mechanism by which TAFs and the Zta activation domain cooperate to stimulate transcription.

Direct recognition of initiator elements by a component of the transcription factor IID complex

A core promoter element called an initiator (Inr) overlaps the transcription start site of numerous mammalian protein-coding genes. In promoters that lack a TATA box, the Inr is functionally analogous to TATA, in that it is capable of directing basal transcription by RNA polymerase II and of determining the precise site of transcription initiation. In promoters that contain a TATA box, the Inr can greatly enhance promoter strength. Mammalian Inr consensus sequences have been defined through functional studies and sequence comparisons of the start site regions of protein-coding genes. Here, we show that, in a DNase I footprinting assay with synthetic promoters, the purified TATA-binding protein complex TFIID specifically contacted the Inr. The TFIID-Inr interaction relies on the precise nucleotides needed for Inr function. Detection of the interaction was dependent either on a TATA box or on Sp1 bound to upstream sites. Furthermore, recombinant TFIIB appeared to influence the TFIID-Inr interaction, whereas TFIIA stabilized the TFIID-TATA interaction. These results demonstrate that distinct components of TFIID interact with the TATA boxes and Inr elements of core promoters for RNA polymerase II.

Sequence of a 28.6 kb region of yeast chromosome XI includes the FBA1 and TOA2 genes, an open reading frame (ORF) similar to a translationally controlled tumour protein, one ORF containing motifs also found in plant storage proteins and 13 ORFs with weak or no homology to known proteins

The complete DNA sequence of cosmid clone pUKG148 comprising 28,600 base pairs was determined from an ordered set of subclones. The sequence contains 22 open reading frames longer than 100 amino acids of which five are entirely covered by other, longer reading frames. YKL054 exhibits 25% homology at the amino acid level to a number of plant storage proteins of the glutenin type, YKL056 is 40% homologous to a translationally controlled mammalian tumour protein, YKL058 (TOA2) is identical to the small subunit of transcription factor TFIIA from yeast and YKL060 is identical to the FBA1 gene also from yeast, already sequenced but not mapped to chromosome XI. The remaining 13 open reading frames show weak or no homology to known genes.

The role of activators in assembly of RNA polymerase II transcription complexes

The past year has provided new insights into the biochemical mechanism of gene activation. Key discoveries include the finding that TFIIA plays an important regulatory role in transcription complex assembly, the TBP-associated factors are direct targets of at least two classes of activator, and a largely pre-assembled transcription complex has been isolated from yeast cells, challenging the step-wise assembly pathway. This review also presents an update on the argument that TFIIB is the target of VP16 and insights into the energetic role of ATP in RNA polymerase II initiation.

An RNA polymerase II holoenzyme responsive to activators

RNA polymerase II requires multiple general transcription factors to initiate site-specific transcription. These proteins can assemble in an ordered fashion onto promoter DNA in vitro, and such ordered assembly may occur in vivo (Fig. 1a). Some general transcription factors can interact with RNA polymerase II in the absence of DNA, however, suggesting that RNA polymerase II may also assemble into a multi-component complex containing a subset of initiation factors before binding to promoter DNA (Fig. 1b). Here we present evidence from the yeast Saccharomyces cerevisiae for such an RNA polymerase II holoenzyme, a multi-subunit complex containing roughly equimolar amounts of RNA polymerase II, a subset of general transcription factors, and SRB regulatory proteins. Transcription by this holoenzyme is stimulated by the activator protein GAL4-VP16, a feature not observed with purified RNA polymerase II and general transcription factors alone. We propose that the holoenzyme is a form of RNA polymerase II readily recruited to promoters in vivo.

Accurate initiation of mRNA synthesis in extracts from Schizosaccharomyces pombe, Kluyveromyces lactis and Candida glabrata

We demonstrate the successful adaptation to other yeast species of a protocol previously described for production of transcriptionally active whole cell extracts from Saccharomyces cerevisiae (Woontner and Jaehning, 1990, J. Biol. Chem. 265, 8979-8982). Extracts prepared from Schizosaccharomyces pombe, Kluyveromyces lactis and Candida glabrata were all capable of initiating transcription from a template containing the S. cerevisiae CYC1 TATA box fused to a G-less cassette. Transcription in all of the extracts was sensitive to inhibition by alpha-amanitin, indicating that it was catalysed by RNA polymerase II, and was dramatically stimulated by the chimeric activator GAL4/VP16. The different extracts used different subsets of a group of three initiation sites.

Altered promoter binding of the TATA box-binding factor induced by the transcriptional activation domain of VP16 and suppressed by TFIIA

The acidic transcriptional activation domain of the Herpes simplex virus protein VP16 has been shown to bind directly to both the TATA box-binding factor TBP and the general initiation factor TFIIB. Using DNase I footprinting assays, we have shown here that the VP16 activation domain qualitatively alters binding of Saccharomyces cerevisiae TBP to a TATA sequence in DNA. The effect of VP16 on promoter binding by TBP was reduced by mutations in VP16 known to reduce transactivation and could not be overcome by increasing the amount of TBP used in the footprinting assays. However, the association of yeast TFIIA with TBP on the promoter reversed the VP16-mediated effect and restored normal binding of TBP to the promoter. We suggest that VP16 induces a conformational change in TBP which alters its binding to promoter DNA, and that this effect of VP16 is suppressed by TFIIA.

Drosophila TFIIA-L is processed into two subunits that are associated with the TBP/TAF complex

The basal factor TFIIA has been shown to act early during initiation in both the mammalian and yeast transcription systems, but a TFIIA-like activity has not been identified in Drosophila. While characterizing the Drosophila TFIID complex, we discovered that a 30-kD protein that cofractionated with dTFIID was homologous to the previously identified, large subunit of yeast TFIIA. Here, we report the cloning and biochemical characterization of Drosophila TFIIA-L. Coimmunoprecipitation studies with anti-dTBP, anti-dTFIIA-L, and anti-TAF antibodies indicated a tight association of the endogenous dTFIIA and dTFIID. However, dTFIIA could be dissociated from dTFIID under conditions that did not elute the TAFs, and the eluted material had mobility shift and transcriptional activities associated with TFIIA. Peptide sequence and Western analysis with antibodies raised against the amino- and carboxy-terminal portions of recombinant dTFIIA-L revealed that a precursor 48-kD species was cleaved in vivo, giving rise to the 30- and 20-kD subunits of dTFIIA that remain associated with each other and with dTFIID. Protein-protein interaction assays identified dTBP and dTAFII110 as targets for binding TFIIA in the TFIID complex. These results suggest that TFIIA may form a specific complex with both TAFs and other components of the transcriptional machinery during formation of the initiation complex.

A single cDNA, hTFIIA/alpha, encodes both the p35 and p19 subunits of human TFIIA

TFIIA is a transcription factor that, by interacting with the TATA-binding subunit (TBP) of TFIID, modulates transcription initiation by RNA polymerase II in vitro. By use of a mobility shift assay, TFIIA was purified from HeLa cells as a complex of 35-, 19-, and 12-kD subunits. Oligonucleotides were used to isolate a human cDNA clone, hTFIIA/alpha, which encodes a 55-kD protein with homology to the product of the yeast gene TOA1. The open reading frame of hTFIIA/alpha contains peptide sequences obtained from both the p35 and p19 subunits of natural human TFIIA, and thus encodes these two subunits. Consistent with this, antiserum raised against the 55-kD hTFIIA/alpha-encoded protein reacted with both the p35 and p19 subunits of natural TFIIA, and the recombinant protein could functionally replace those subunits in a mobility shift assay with renatured p12. An efficient affinity purification for natural human TFIIA was suggested by the sequence of the hTFIIA/alpha protein and demonstrated biochemically. Finally, transcription from the adenovirus major late promoter was greatly reduced in nuclear extracts depleted with anti-TFIIA/alpha serum and was restored to original levels by the readdition of purified human TFIIA.

ADA3: a gene, identified by resistance to GAL4-VP16, with properties similar to and different from those of ADA2

We describe the isolation of a yeast gene, ADA3, mutations in which prevent the toxicity of GAL4-VP16 in vivo. Toxicity was previously proposed to be due to the trapping of general transcription factors required at RNA polymerase II promoters (S. L. Berger, B. Piña, N. Silverman, G. A. Marcus, J. Agapite, J. L. Regier, S. J. Triezenberg, and L. Guarente, Cell 70:251-265, 1992). trans activation by VP16 as well as the acidic activation domain of GCN4 is reduced in the mutant. Other activation domains, such as those of GAL4 and HAP4, are only slightly affected in the mutant. This spectrum is similar to that observed for mutants with lesions in ADA2, a gene proposed to encode a transcriptional adaptor. The ADA3 gene is not absolutely essential for cell growth, but gene disruption mutants grow slowly and are temperature sensitive. Strains doubly disrupted for ada2 and ada3 grow no more slowly than single mutants, providing further evidence that these genes function in the same pathway. Selection of initiation sites by the general transcriptional machinery in vitro is altered in the ada3 mutant, providing a clue that ADA3 could be a novel general transcription factor involved in the response to acidic activators.

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.

ADA3: a gene, identified by resistance to GAL4-VP16, with properties similar to and different from those of ADA2

We describe the isolation of a yeast gene, ADA3, mutations in which prevent the toxicity of GAL4-VP16 in vivo. Toxicity was previously proposed to be due to the trapping of general transcription factors required at RNA polymerase II promoters (S. L. Berger, B. Piña, N. Silverman, G. A. Marcus, J. Agapite, J. L. Regier, S. J. Triezenberg, and L. Guarente, Cell 70:251-265, 1992). trans activation by VP16 as well as the acidic activation domain of GCN4 is reduced in the mutant. Other activation domains, such as those of GAL4 and HAP4, are only slightly affected in the mutant. This spectrum is similar to that observed for mutants with lesions in ADA2, a gene proposed to encode a transcriptional adaptor. The ADA3 gene is not absolutely essential for cell growth, but gene disruption mutants grow slowly and are temperature sensitive. Strains doubly disrupted for ada2 and ada3 grow no more slowly than single mutants, providing further evidence that these genes function in the same pathway. Selection of initiation sites by the general transcriptional machinery in vitro is altered in the ada3 mutant, providing a clue that ADA3 could be a novel general transcription factor involved in the response to acidic activators.

DNA melting on yeast RNA polymerase II promoters

Transcription-dependent DNA melting on the yeast GAL1 and GAL10 promoters was found to be more closely correlated with the TATA box than the transcription start site. On both these genes, melting begins about 20 base pairs downstream of the TATA box. Physical and genetic analyses suggest that RNA polymerase II associates with this region. Thus, the distance between promoter melting and the TATA box in yeast may be similar to that in higher eukaryotes, even though transcription initiates in a region about 10 to 90 base pairs farther downstream in yeast.

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.

Yeast transcription factors

Studies of yeast transcription factors have contributed greatly to understanding basic molecular mechanisms of eukaryotic gene regulation, largely due to powerful genetic approaches that are unavailable in other organisms. The broad outlines of these mechanisms are fairly well understood, and there is an increasing number of examples where detailed information is available.

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.