A cDNA encoding RAP74, a general initiation factor for transcription by RNA polymerase II

The general transcription machinery and general cofactors

In eukaryotes, the core promoter serves as a platform for the assembly of transcription preinitiation complex (PIC) that includes TFIIA, TFIIB, TFIID, TFIIE, TFIIF, TFIIH, and RNA polymerase II (pol II), which function collectively to specify the transcription start site. PIC formation usually begins with TFIID binding to the TATA box, initiator, and/or downstream promoter element (DPE) found in most core promoters, followed by the entry of other general transcription factors (GTFs) and pol II through either a sequential assembly or a preassembled pol II holoenzyme pathway. Formation of this promoter-bound complex is sufficient for a basal level of transcription. However, for activator-dependent (or regulated) transcription, general cofactors are often required to transmit regulatory signals between gene-specific activators and the general transcription machinery. Three classes of general cofactors, including TBP-associated factors (TAFs), Mediator, and upstream stimulatory activity (USA)-derived positive cofactors (PC1/PARP-1, PC2, PC3/DNA topoisomerase I, and PC4) and negative cofactor 1 (NC1/HMGB1), normally function independently or in combination to fine-tune the promoter activity in a gene-specific or cell-type-specific manner. In addition, other cofactors, such as TAF1, BTAF1, and negative cofactor 2 (NC2), can also modulate TBP or TFIID binding to the core promoter. In general, these cofactors are capable of repressing basal transcription when activators are absent and stimulating transcription in the presence of activators. Here we review the roles of these cofactors and GTFs, as well as TBP-related factors (TRFs), TAF-containing complexes (TFTC, SAGA, SLIK/SALSA, STAGA, and PRC1) and TAF variants, in pol II-mediated transcription, with emphasis on the events occurring after the chromatin has been remodeled but prior to the formation of the first phosphodiester bond.

Identification of differentially expressed genes HSPC016 in dermal papilla cells with aggregative behavior

The dermal papilla plays pivotal roles in hair follicle cycle and dermal papilla cells (DPCs) with aggregative behavior have more obviously inductive ability. In the present study, the suppression subtractive hybridization method was employed to identify the differentially expressed genes in dermal papillae cells with aggregative behavior. Following mRNA isolation of DPC with and without aggregative behavior, cDNA of both populations were prepared and subtracted by suppression PCR. Sequencing of enriched cDNAs identified five genes differentially expressed including capping protein, paladin, and vascular endothelial growth factor. Interestingly, HSPC016, first cloned from CD34+ hematopoietic stem/progenitor cells (HSPC), was identified by SSH, cDNA dot blot and Northern blot, which showed that this gene was differentially expressed in DPC with aggregative behavior. The full-length cDNA of HSPC016 was shown to be 366 bp, and the possible function of HSPC016 related to transcriptional regulation.

The highly conserved glutamic acid 791 of Rpb2 is involved in the binding of NTP and Mg(B) in the active center of human RNA polymerase II

During transcription by RNA polymerase (RNAP) II, the incoming ribonucleoside triphosphate (NTP) enters the catalytic center in association with an Mg2+ ion, termed metal B [Mg(B)]. When bound to RNAP II, Mg(B) is coordinated by the beta and gamma phosphates of the NTP, Rpb1 residues D481 and D483 and Rpb2 residue D837. Rpb2 residue D837 is highly conserved across species. Notably, its neighboring residue, E836 (E791 in human RNAP II), is also highly conserved. To probe the role of E791 in transcription, we have affinity purified and characterized a human RNAP II mutant in which this residue was substituted for alanine. Our results indicate that the transcription activity of the Rpb2 E791A mutant is impaired at low NTP concentrations both in vitro and in vivo. They also revealed that both its NTP polymerization and transcript cleavage activities are decreased at low Mg concentrations. Because Rpb2 residue E791 appears to be located too far from the NTP-Mg(B) complex to make direct contact at either the entry (E) or addition (A) site, we propose alternative mechanisms by which this highly conserved residue participates in loading NTP-Mg(B) in the active site during transcription.

RPAP1, a novel human RNA polymerase II-associated protein affinity purified with recombinant wild-type and mutated polymerase subunits

We have programmed human cells to express physiological levels of recombinant RNA polymerase II (RNAPII) subunits carrying tandem affinity purification (TAP) tags. Double-affinity chromatography allowed for the simple and efficient isolation of a complex containing all 12 RNAPII subunits, the general transcription factors TFIIB and TFIIF, the RNAPII phosphatase Fcp1, and a novel 153-kDa polypeptide of unknown function that we named RNAPII-associated protein 1 (RPAP1). The TAP-tagged RNAPII complex is functionally active both in vitro and in vivo. A role for RPAP1 in RNAPII transcription was established by shutting off the synthesis of Ydr527wp, a Saccharomyces cerevisiae protein homologous to RPAP1, and demonstrating that changes in global gene expression were similar to those caused by the loss of the yeast RNAPII subunit Rpb11. We also used TAP-tagged Rpb2 with mutations in fork loop 1 and switch 3, two structural elements located strategically within the active center, to start addressing the roles of these elements in the interaction of the enzyme with the template DNA during the transcription reaction.

The RNA polymerase II transcription cycle: cycling through chromatin

The cycle of events that characterizes RNA polymerase II transcription has been the focus of intense study over the past two decades. Our knowledge of the molecular processes leading to transcriptional initiation is greatly improved, and the focus of many recent studies has shifted towards the less well-characterized events taking place after assembly of the pre-initiation complex, such as promoter clearance, elongation, and termination. This review gives a brief overview of the transcription cycle as a whole, focusing especially on selected mechanisms that may drive or restrict the cycle, and on how the presence of chromatin may influence these mechanisms.

Photo-cross-linking of a purified preinitiation complex reveals central roles for the RNA polymerase II mobile clamp and TFIIE in initiation mechanisms

The topological organization of a TATA binding protein-TFIIB-TFIIF-RNA polymerase II (RNAP II)-TFIIE-promoter complex was analyzed using site-specific protein-DNA photo-cross-linking of gel-purified complexes. The cross-linking results for the subunits of RNAP II were used to determine the path of promoter DNA against the structure of the enzyme. The results indicate that promoter DNA wraps around the mobile clamp of RNAP II. Cross-linking of TFIIF and TFIIE both upstream of the TATA element and downstream of the transcription start site suggests that both factors associate with the RNAP II mobile clamp. TFIIE alpha closely approaches promoter DNA at nucleotide -10, a position immediately upstream of the transcription bubble in the open complex. Increased stimulation of transcription initiation by TFIIE alpha is obtained when the DNA template is artificially premelted in the -11/-1 region, suggesting that TFIIE alpha facilitates open complex formation, possibly through its interaction with the upstream end of the partially opened transcription bubble. These results support the central roles of the mobile clamp of RNAP II and TFIIE in transcription initiation.

A key role for the alpha 1 helix of human RAP74 in the initiation and elongation of RNA chains

RNA polymerase II-associating protein 74 (RAP74) is the large subunit of transcription factor IIF (TFIIF), which is essential for accurate initiation and stimulates elongation by RNA polymerase II. Mutations within or adjacent to the alpha1 helix of the RAP74 subunit have been shown to decrease both initiation and elongation stimulation activities without strongly affecting the interactions of RAP74 with the RAP30 subunit or the interaction between TFIIF and RNA polymerase II. In this manuscript, mutations within the alpha1 helix are compared with mutations made throughout the neighboring conserved N-terminal domain of RAP74. Changes within the N-terminal domain include disruptions of specific contacts with the alpha1 helix, which were revealed in the recently published x-ray crystal structure (Gaiser, F., Tan, S., and Richmond, T. J. (2000) J. Mol. Biol. 302, 1119-1127). Contacts between the beta4-beta5 loop and the alpha1 helix are shown to be largely unimportant for alpha1 helix function. Other mutations throughout the N-terminal domain are consistent with the establishment of the dimer interface with the RAP30 subunit. The RAP74-RAP30 interface is important for TFIIF function, but no particular RAP74 amino acids within this region have been identified that are required for TFIIF activities. The molecular target of the alpha1 helix remains unknown, but our studies refocus attention on this important functional motif of TFIIF.

WRN helicase accelerates the transcription of ribosomal RNA as a component of an RNA polymerase I-associated complex

Werner syndrome (WS) is a rare autosomal recessive genetic disorder causing premature aging. The gene (WRN) responsible for WS encodes a protein homologous to the RecQ-type helicase. WRN has a nucleolar localization signal and shows intranuclear trafficking between the nucleolus and the nucleoplasm. WRN is recruited into the nucleolus when rRNA transcription is reactivated in quiescent cells. Inhibition of mRNA transcription with alpha-amanitin has no effect on nucleolar localization of WRN whereas inhibition of rRNA transcription with actinomycin D releases WRN from nucleoli, suggesting that nucleolar WRN is closely related to rRNA transcription by RNA polymerase I (RPI). A possible function of WRN on rRNA transcription through interaction with RPI is supported by the results described here showing that WRN is co-immunoprecipitated with an RPI subunit, RPA40. Here we show that WS fibroblasts are characterized by a decreased level of rRNA transcription compared with wild-type cells, and that the decreased level of rRNA transcription in WS fibroblasts recovers when wild-type WRN is exogenously expressed. By contrast, exogenously expressed mutant-type WRN lacking an ability to migrate into the nucleolus fails to stimulate rRNA transcription. These results suggest that WRN promotes rRNA transcription as a component of an RPI-associated complex in the nucleolus.

Structural and functional interactions of transcription factor (TF) IIA with TFIIE and TFIIF in transcription initiation by RNA polymerase II

A topological model for transcription initiation by RNA polymerase II (RNAPII) has recently been proposed. This model stipulates that wrapping of the promoter DNA around RNAPII and the general initiation factors TBP, TFIIB, TFIIE, TFIIF and TFIIH induces a torsional strain in the DNA double helix that facilitates strand separation and open complex formation. In this report, we show that TFIIA, a factor previously shown to both stimulate basal transcription and have co-activator functions, is located near the cross-point of the DNA loop where it can interact with TBP, TFIIE56, TFIIE34, and the RNAPII-associated protein (RAP) 74. In addition, we demonstrate that TFIIA can stimulate basal transcription by stimulating the functions of both TFIIE34 and RAP74 during the initiation step of the transcription reaction. These results provide novel insights into mechanisms of TFIIA function.

Cyclin D1 suppresses retinoblastoma protein-mediated inhibition of TAFII250 kinase activity

The retinoblastoma tumor suppressor protein has been shown to bind directly and inhibit a transcriptionally-important amino-terminal kinase domain of TATA-binding protein-associated factor TAFII250. Cyclin D1 also is able to associate with the amino terminus of TAFII250 in a region very similar to or overlapping the Rb-binding site. In this study, we have examined whether cyclin D1 affects the functional interaction between Rb and TAFII250. We observed that when cyclin D1 is coincubated with Rb and TAFII250, the ability of Rb to inhibit TAFII250 kinase activity is effectively blocked. However, cyclin D1 by itself has no apparent effect on TAFII250 kinase activity. We further found that the Rb-related protein p107 can inhibit TAFII250 kinase activity, and this inhibition is likewise alleviated by cyclin D1. Cyclin D1 prevents the kinase-inhibitory effect of an Rb mutant unable to bind to D-type cyclins, indicating that it is acting through its association with TAFII250 and not with Rb. However, we found no evidence of TAFII250-binding competition between Rb and cyclin D1 in vitro. The adenovirus E1A protein, which also binds to both Rb and TAFII250, exhibited a suppressive effect on Rb-mediated kinase inhibition similar to that seen with cyclin D1. Our results suggest a novel means by which cyclin D1 may be able to independently regulate the activity of Rb.

Phosphorylation of the RAP74 subunit of TFIIF correlates with Tat-activated transcription of the HIV-1 long terminal repeat

Transcription from the HIV-1 long terminal repeat (LTR) is regulated by the viral transactivator Tat, which increases RNA polymerase II (RNAP II) processivity. Previous reports have demonstrated that phosphorylation of the RNAP II carboxy-terminal domain by TFIIH and P-TEFb is important for Tat transactivation. Our present results demonstrate that phosphorylation of the RAP74 subunit of TFIIF is also an important step in Tat transactivation. Interestingly, while the general transcription factor TFIIF is required for both basal and Tat-activated transcription, phosphorylation of the RAP74 subunit occurs in the presence of Tat and correlates with a high level of transcription activity. Using a biotinylated DNA template transcription assay, we provide evidence that RAP74 is phosphorylated by TAF(II)250 during Tat-activated transcription. Depletion of RAP74 from the HeLa nuclear extract inhibited HIV-1 LTR-driven basal transcription and Tat transactivation. The addition of TFIIF, reconstituted from recombinant RAP30 and RAP74, to the depleted HeLa nuclear extract resulted in restoration of Tat transactivation. Of importance, the exogenous RAP74 was rapidly phosphorylated in the presence of Tat. These results suggest that RAP74 phosphorylation is one important step, of several, in the Tat transactivation cascade.

Acetyl coenzyme A stimulates RNA polymerase II transcription and promoter binding by transcription factor IID in the absence of histones

Protein acetylation has emerged as a means of controlling levels of mRNA synthesis in eukaryotic cells. Here we report that acetyl coenzyme A (acetyl-CoA) stimulates RNA polymerase II transcription in vitro in the absence of histones. The effect of acetyl-CoA on basal and activated transcription was studied in a human RNA polymerase II transcription system reconstituted from recombinant and highly purified transcription factors. Both basal and activated transcription were stimulated by the addition of acetyl-CoA to transcription reaction mixtures. By varying the concentrations of general transcription factors in the reaction mixtures, we found that acetyl-CoA decreased the concentration of TFIID required to observe transcription. Electrophoretic mobility shift assays and DNase I footprinting revealed that acetyl-CoA increased the affinity of the general transcription factor TFIID for promoter DNA in a TBP-associated factor (TAF)-dependent manner. Interestingly, acetyl-CoA also caused a conformational change in the TFIID-TFIIA-promoter complex as assessed by DNase I footprinting. These results show that acetyl-CoA alters the DNA binding activity of TFIID and indicate that this biologically important cofactor functions at multiple levels to control gene expression.

A region within the RAP74 subunit of human transcription factor IIF is critical for initiation but dispensable for complex assembly

Human transcription factor IIF (TFIIF) is an alpha(2)beta(2) heterotetramer of RNA polymerase II-associating 74 (RAP74) and RAP30 subunits. Mutagenic analysis shows that the N-terminal region of RAP74 between L155 (leucine at codon 155) and M177 is important for initiation. Mutants in this region have reduced activity in transcription, but none are inactive. Single amino acid substitutions at hydrophobic residues L155, W164, I176, and M177 have similar activity to RAP74(1-158), from which all but three amino acids of this region are deleted. Residual activity can be explained because each of these mutants forms a complex with RAP30 and recruits RNA polymerase II into the preinitiation complex. Mutants are defective for formation of the first phosphodiester bond from the adenovirus major late promoter but do not appear to have an additional significant defect in promoter escape. Negative DNA supercoiling partially compensates for the defects of TFIIF mutants in initiation, indicating that TFIIF may help to untwist the DNA helix for initiation.

Rb inhibits the intrinsic kinase activity of TATA-binding protein-associated factor TAFII250

The retinoblastoma tumor suppressor protein, Rb, interacts directly with the largest TATA-binding protein-associated factor, TAFII250, through multiple regions in each protein. To define the potential role(s) of this interaction, we examined whether Rb could regulate the intrinsic, bipartite kinase activity of TAFII250. Here, we report that Rb is able to inhibit the kinase activity of immunopurified and gel-purified recombinant TAFII250. Rb inhibits the autophosphorylation of TAFII250 as well as its phosphorylation of the RAP74 subunit of TFIIF in a dose-responsive manner. Inhibition of TAFII250 kinase activity involves the Rb pocket (amino acids 379 to 928) but not its amino terminus. In addition, Rb appears to specifically inhibit the amino-terminal kinase domain of TAFII250 through a direct protein-protein interaction. We further demonstrate that two different tumor-derived Rb pocket mutants, C706F and Deltaex22, are functionally defective for kinase inhibition, even though they are able to bind the amino terminus of TAFII250. Our results suggest a novel mechanism of transcriptional regulation by Rb, involving direct interaction with TAFII250 and inhibition of its ability to phosphorylate itself, RAP74, and possibly other targets.

Structure of the human transcription factor TFIIF revealed by limited proteolysis with trypsin

In this study, the human general transcription factor IIF (TFIIF), a heteromeric complex of RAP74 and RAP30 subunits, was subjected to limited proteolysis with trypsin. The central region of RAP74 was demonstrated to be highly sensitive to trypsin while both the N- and C-terminal regions contained trypsin-resistant structures. In contrast, RAP30 digestion occurred after proteolysis of RAP74. The digestion pattern of RAP74 recruited into the preinitiation complex showed no marked difference from that of IIF, while RAP30 in the complex was protected from trypsin. These results indicate that RAP74 apparently contains three structural domains, the central one of which is externally surfaced and unstructured, but RAP30 is internally wrapped by RAP74. Furthermore, the accessibility of the central region of RAP74 is unaltered in the minimal preinitiation complex, while RAP30 is involved in promoter recognition through its DNA binding activity.

Promoter escape limits the rate of RNA polymerase II transcription and is enhanced by TFIIE, TFIIH, and ATP on negatively supercoiled DNA

To measure rate constants for discrete steps of single-round transcription (preinitiation complex formation, promoter escape, and transcript elongation), kinetic studies were performed in a well defined human RNA polymerase II transcription system. These experiments revealed that promoter escape limits the rate of transcription from the adenovirus major late promoter (AdMLP) contained on negatively supercoiled DNA. TFIIE and TFIIH were found to significantly increase fractional template usage during a single round of transcription in an ATP-dependent reaction. The observed rate constant for promoter escape, however, was not greatly affected by TFIIE and TFIIH. Our results are explained by a model in which transcription branches into at least two pathways: one that results in functional promoter escape and full-length RNA synthesis, and another in which preinitiation complexes abort during promoter escape and do not produce full-length RNA transcripts. These results with negatively supercoiled templates agree with our earlier conclusion that TFIIE, TFIIH, and ATP direct promoter escape and support a model in which the TFIIH helicases stimulate promoter escape in an ATP-dependent reaction.

Functions of the N- and C-terminal domains of human RAP74 in transcriptional initiation, elongation, and recycling of RNA polymerase II

Transcription factor IIF (TFIIF) cooperates with RNA polymerase II (pol II) during multiple stages of the transcription cycle including preinitiation complex assembly, initiation, elongation, and possibly termination and recycling. Human TFIIF appears to be an alpha2beta2 heterotetramer of RNA polymerase II-associating protein 74- and 30-kDa subunits (RAP74 and RAP30). From inspection of its 517-amino-acid (aa) sequence, the RAP74 subunit appears to comprise separate N- and C-terminal domains connected by a flexible loop. In this study, we present functional data that strongly support this model for RAP74 architecture and further show that the N- and C-terminal domains and the central loop of RAP74 have distinct roles during separate phases of the transcription cycle. The N-terminal domain of RAP74 (minimally aa 1 to 172) is sufficient to deliver pol II into a complex formed on the adenovirus major late promoter with the TATA-binding protein, TFIIB, and RAP30. A more complete N-terminal domain fragment (aa 1 to 217) strongly stimulates both accurate initiation and elongation by pol II. The region of RAP74 between aa 172 and 205 and a subregion between aa 170 and 178 are critical for both accurate initiation and elongation, and mutations in these regions have similar effects on initiation and elongation. Based on these observations, RAP74 appears to have similar functions in initiation and elongation. The central region and the C-terminal domain of RAP74 do not contribute strongly to single-round accurate initiation or elongation stimulation but do stimulate multiple-round transcription in an extract system.

[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.

Cell-cycle-dependent phosphorylation of the basal transcription factor RAP74

In this report, cell-cycle-dependent effects of TFIID on other basal transcription factors were investigated. We purified TFIID fractions from HeLa cells synchronized in the S/G2 phases and in early G1 phase, and show that RAP74 is phosphorylated more highly by the S/G2 phase TFIID fraction than by the early G1 phase TFIID fraction. Further analyses using deletion mutants of RAP74 revealed that amino acid residues 206-256 are phosphorylated by the TFIID fraction. Reconstitution of in vitro transcription activity indicates that the cell-cycle-dependent phosphorylation of RAP74 increases TFIIF transcription activity.

TFG/TAF30/ANC1, a component of the yeast SWI/SNF complex that is similar to the leukemogenic proteins ENL and AF-9

The SWI1/ADR6, SWI2/SNF2, SWI3, SNF5, and SNF6 gene products are all required for proper transcriptional control of many genes in the yeast Saccharomyces cerevisiae. Genetic studies indicated that these gene products might form a multiprotein SWI/SNF complex important for chromatin transitions preceding transcription from RNA polymerase II promoters. Biochemical studies identified a SWI/SNF complex containing these and at least six additional polypeptides. Here we show that the 29-kDa component of the SWI/SNF complex is identical to TFG3/TAF30/ANC1. Thus, a component of the SWI/SNF complex is also a member of the TFIIF and TFIID transcription complexes. TFG3 interacted with the SNF5 component of the SWI/SNF complex in protein interaction blots. TFG3 is significantly similar to ENL and AF-9, two proteins implicated in human acute leukemia. These results suggest that ENL and AF-9 proteins interact with the SNF5 component of the human SWI/SNF complex and raise the possibility that the SWI/SNF complex is involved in acute leukemia.

Characterization of the interaction between the acidic activation domain of VP16 and the RNA polymerase II initiation factor TFIIB

Contact between a transcriptional activator and one or more components of the RNA polymerase II transcription initiation machinery is generally believed important for activators to function. Several different molecular targets have been suggested for direct contact by herpes simplex virus virion protein VP16, including the general initiation factor TFIIB. In this report we have used several strategies to critically assess this interaction between VP16 and TFIIB. Affinity columns of VP16 bound TFIIB activity from HeLa cell extracts and the binding was reduced by mutations in the activation domain of VP16. In assays of direct binding, VP16 bound recombinant human TFIIB but not Drosophila or yeast TFIIB. Unlike binding from an extract, however, we found that the interaction between VP16 and recombinant human TFIIB was not affected by mutations in VP16 that reduce transactivation. Point mutations within human TFIIB that reduce transactivation by VP16 have been shown to reduce VP16 binding, but we show here that these same mutations critically affect both the important TBP-TFIIB interaction and the ability of TFIIB to support activator-independent basal transcription in vitro. Taken together our results suggest more evidence is needed to support the notion that TFIIB is a functionally important target for the activator VP16.

The embryonic transcription factor stage specific activator protein contains a potent bipartite activation domain that interacts with several RNA polymerase II basal transcription factors

Stage specific activator protein (SSAP) is a member of a newly discovered class of transcription factors that contain motifs more commonly found in RNA-binding proteins. Previously, we have shown that SSAP specifically binds to its recognition sequence in both the double strand and the single strand form and that this DNA-binding activity is localized to the N-terminal RNA recognition motif domain. Three copies of this recognition sequence constitute an enhancer element that is directly responsible for directing the transcriptional activation of the sea urchin late histone H1 gene at the midblastula stage of embryogenesis. Here we show that the remainder of the SSAP polypeptide constitutes an extremely potent bipartite transcription activation domain that can function in a variety of mammalian cell lines. This activity is as much as 3 to 5 times stronger than VP16 at activating transcription and requires a large stretch of amino acids that contain glutamine-glycine rich and serine-threonine-basic amino acid rich regions. We present evidence that SSAP's activation domain shares targets that are also necessary for activation by E1a and VP16. Finally, SSAP's activation domain is found to participate in specific interactions in vitro with the basal transcription factors TATA-binding protein, TFIIB, TFIIF74, and dTAF(II) 110.

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.

Localization of subunits of transcription factors IIE and IIF immediately upstream of the transcriptional initiation site of the adenovirus major late promoter

The assembly of a preinitiation complex containing RNA polymerase II on promoter DNA is a complex process that involves several general transcription factors. Using 5-[N-(p-azidobenzoyl)-3-aminoallyl] photocross-linking, we previously determined the locations of the two large subunits of transcription factor (TF) IIA (A35 and A21), TATA box-binding protein (TBP), RNA polymerase II-associated protein (RAP) 30, and TFIIB along the Ad2 ML promoter. We have now localized TFIIE34 and RAP74 just upstream of the transcription start site. The two subunits of TFIIF, RAP74 and RAP30, cross-linked to nucleotides that probed adjacent spaces on the same face of the DNA helix beginning just downstream of TBP at -19 and extending to -5. Specific photocross-linking of TFIIE34 required the presence TFIIE56. In addition, TFIIE and RAP74 strongly stimulated cross-linking of RAP30 and the large subunits of RNA polymerase II to position -19. Our topological data support the idea that RAP74 and TFIIE34 may be involved in melting of the promoter DNA upstream of the initiation site.

Human TAFII250 interacts with RAP74: implications for RNA polymerase II initiation

Accurate and regulated transcription by RNA polymerase II requires the assembly of an initiation complex involving multiple protein-DNA and protein-protein interactions. A key event is binding of TFIID, a complex consisting of TBP and associated factors (TAFs) to the template DNA. The TAF subunits of TFIID carry out diverse functions critical for transcription, including specific contact with enhancer proteins and binding to core promoter DNA. However, the role of TAFs in RNA polymerase II-mediated transcription initiation and cross talk with other basal factors remains poorly characterized. Here, we report the specific interaction of TAFII250 with RAP74, an essential subunit of the basal transcription factor IIF. Using various in vitro binding assays we have mapped recognition interfaces between TAFII250 and RAP74. In vivo complementation of a temperature-sensitive TAFII250 cell line reveals that the RAP74 interaction is critical for cell viability. Because TFIIF is thought to be responsible for binding and recruiting RNA polymerase II, the ability of TAFII250 to interact selectively with RAP74 is likely to contribute a critical contact for the assembly of an active transcription complex.

Functional domains of human RAP74 including a masked polymerase binding domain

RAP74, the large subunit of human transcription factor IIF (TFIIF), has been analyzed by deletion mutagenesis and in vitro assays to map functional domains. Tight binding to the RAP30 subunit involves amino acids between positions 1-172. Amino acids 1-205 are minimally sufficient to stimulate accurate transcription from the adenovirus major late promoter in an extract system, although C-terminal sequences contribute to activity. A partially masked RNA polymerase II binding domain has been mapped to the C-terminal region of the protein (amino acids 363-444). Sequences near the N terminus and within the central portion of RAP74 affect accessibility of this domain. Extending this domain to 363-486 creates a peptide that binds polymerase and DNA and inhibits transcription initiation in vitro from non-promoter DNA sites. This larger C-terminal domain may modify polymerase interaction with template during initiation and/or elongation of RNA chains.

Identification of human autoantibodies to transcription factor IIB

We have characterized the ability of various human autoimmune sera to react with RNA polymerase II transcription factors. One serum, which strongly inhibited transcription in a cell-free system, was shown to contain antibodies directed against human TFIIB. The serum did not show reactivity against the other general transcription factors, including human TBP, TFIIE and TFIIF. The inhibition of transcription was directly attributable to depletion of TFIIB activity, as demonstrated by reconstitution of activity with recombinant TFIIB. It has long been recognized that components of the RNA processing machinery are major human autoantigens. The present results show that at least one general transcription factor required for messenger RNA synthesis is an autoantigen as well.

The activity of COOH-terminal domain phosphatase is regulated by a docking site on RNA polymerase II and by the general transcription factors IIF and IIB

Each cycle of transcription appears to be associated with the reversible phosphorylation of the repetitive COOH-terminal domain (CTD) of the largest RNA polymerase (RNAP) II subunit. The dephosphorylation of RNAP II by CTD phosphatase, therefore, plays an important role in the transcription cycle. The following studies characterize the activity of HeLa cell CTD phosphatase with a special emphasis on the regulation of CTD phosphatase activity. Results presented here suggest that RNAP II contains a docking site for CTD phosphatase that is essential in the dephosphorylation reaction and is distinct from the CTD. This is supported by the observations that (a) phosphorylated recombinant CTD is not a substrate for CTD phosphatase, (b) RNAP IIB, which lacks the CTD, and RNAP IIA are competitive inhibitors of CTD phosphatase and (c) CTD phosphatase can form a stable complex with RNAP II. To test the possibility that the general transcription factors may be involved in the regulation of CTD phosphatase, CTD phosphatase activity was examined in the presence of recombinant or highly purified general transcription factors. TFIIF stimulates CTD phosphatase activity 5-fold. The RAP74 subunit of TFIIF alone contained the stimulatory activity and the minimal region sufficient for stimulation corresponds to COOH-terminal residues 358-517. TFIIB inhibits the stimulatory activity of TFIIF but has no effect on CTD phosphatase activity in the absence of TFIIF. The potential importance of the docking site on RNAP II and the effect of TFIIF and TFIIB in regulating the dephosphorylation of RNAP II at specific times in the transcription cycle are discussed.

Molecular cloning of cDNA encoding the small subunit of Drosophila transcription initiation factor TFIIF

Transcription initiation factor TFIIF is a tetramer consisting of two large subunits (TFIIF alpha or RAP74) and two small subunits (TFIIF beta or RAP30). We report here the molecular cloning of a Drosophila cDNA encoding TFIIF beta. The cDNA clone contains an open-reading frame encoding a 277 amino acid polypeptide having a calculated molecular mass of 32,107 Da. Comparison of the deduced amino acid sequence with the corresponding sequences from vertebrates showed only 50% identity, with four insertion/deletion points. For transcription activity in a TFIIF-depleted Drosophila nuclear extract, both TFIIF alpha and TFIIF beta are essential. Moreover, Drosophila TFIIF beta interacts with both Drosophila and human TFIIF alpha in vitro. Thus we conclude that isolated cDNA encodes bona fide TFIIF beta. The structural domains of TFIIF beta and its sequence similarity to bacterial delta factors are discussed.

Identification of the gene (SSU71/TFG1) encoding the largest subunit of transcription factor TFIIF as a suppressor of a TFIIB mutation in Saccharomyces cerevisiae

Mutations in the Saccharomyces cerevisiae SSU71 gene were isolated as suppressors of a transcription factor TFIIB defect that confers both a cold-sensitive growth defect and a downstream shift in transcription start-site selection at the cyc1 locus. The ssu71-1 suppressor not only suppresses the conditional phenotype but also restores the normal pattern of transcription initiation at cyc1. In addition, the ssu71-1 suppressor confers a heat-sensitive phenotype that is dependent upon the presence of the defective form of TFIIB. Molecular and genetic analysis of the cloned SSU71 gene demonstrated that SSU71 is a single-copy essential gene encoding a highly charged protein with a molecular mass of 82,194 daltons. Comparison of the deduced Ssu71 amino acid sequence with the protein data banks revealed significant similarity to RAP74, the larger subunit of the human general transcription factor TFIIF. Moreover, Ssu71 is identical to p105, a component of yeast TFIIF. Taken together, these data demonstrate a functional interaction between TFIIB and the large subunit of TFIIF and that this interaction can affect start-site selection in vivo.

Structure and function of the small subunit of TFIIF (RAP30) from Drosophila melanogaster

To study the mechanism of basal transcription by RNA polymerase II, a cDNA encoding the Drosophila homologue of the small subunit of TFIIF (also referred to as TFIIF30, RAP30, factor 5b, and gamma) was isolated. The Drosophila TFIIF30 gene is located at region 86C on the right arm of the third chromosome. The protein encoded by the cDNA, termed dTFIIF30, was synthesized in Escherichia coli and purified to greater than 95% homogeneity. In reconstituted transcription reactions with purified basal factors, the specific activity of dTFIIF30 was identical to that of its human homologue. Moreover, a carboxyl-terminal fragment, designated dF30(119-276), which contains the carboxyl-terminal 158 amino acid residues of dTFIIF30, was found to possess approximately 50% of the transcriptional activity as full-length dTFIIF30. The interaction of dTFIIF30 with the large subunit of TFIIF (also referred to as TFIIF74, RAP74, factor 5a, and beta) was investigated by glycerol gradient sedimentation analyses. In these experiments, dTFIIF30, but not dF30(119-276), assembled into a stable heteromeric complex with TFIIF74. These results, combined with those of previous work on TFIIF, support a model for TFIIF30 function in which the carboxylterminal region constitutes a functional domain that can interact with RNA polymerase II to mediate basal transcription, whereas the amino terminus comprises a domain that interacts with TFIIF74.

Interaction with RAP74 subunit of TFIIF is required for transcriptional activation by serum response factor

A few general transcription factors, in particular TFIID and TFIIB, have been found to bind transcriptional activators. Here we show that the general transcription factor TFIIF is also a target for a transcriptional activator, namely serum response factor (SRF), which binds to the c-fos promoter. Using a yeast interaction assay, we find that SRF binds the RAP74 subunit of TFIIF and that SRF's transcriptional activation domain is the region involved in this binding. Further, RAP74's central charged cluster domain is required for binding to SRF's activation domain. Deletion of this domain impairs RAP74's ability to support SRF-activated transcription in vitro but has little effect on the protein's basal transcription activity or its ability to support SP1-activated transcription. The correlation of SRF-RAP74 binding with transcriptional activation suggests that RAP74 is a critical target for SRF-activated transcription.

TFIIF-TAF-RNA polymerase II connection

RNA polymerase transcription factor IIF (TFIIF) is required for initiation at most, if not all, polymerase II promoters. We report here the cloning and sequencing of genes for a yeast protein that is the homolog of mammalian TFIIF. This yeast protein, previously designated factor g, contains two subunits, Tfg1 and Tfg2, both of which are required for transcription, essential for yeast cell viability, and whose sequences exhibit significant similarity to those of the mammalian factor. The yeast protein also contains a third subunit, Tfg3, which is less tightly associated and at most stimulatory to transcription, dispensable for cell viability, and has no known counterpart in mammalian TFIIF. Remarkably, the TFG3 gene encodes yeast TAF30, and furthermore, is identical to ANC1, a gene implicated in actin cytoskeletal function in vivo (Welch and Drubin 1994). Tfg3 is also a component of the recently described mediator complex (Kim et al. 1994), whose interaction with the carboxy-terminal repeat domain of RNA polymerase II enables transcriptional activation. Deletion of TFG3 results in diminished transcription in vivo.

Binding of basal transcription factor TFIIH to the acidic activation domains of VP16 and p53

Acidic transcriptional activation domains function well in both yeast and mammalian cells, and some have been shown to bind the general transcription factors TFIID and TFIIB. We now show that two acidic transactivators, herpes simplex virus VP16 and human p53, directly interact with the multisubunit human general transcription factor TFIIH and its Saccharomyces cerevisiae counterpart, factor b. The VP16- and p53-binding domains in these factors lie in the p62 subunit of TFIIH and in the homologous subunit, TFB1, of factor b. Point mutations in VP16 that reduce its transactivation activity in both yeast and mammalian cells weaken its binding to both yeast and human TFIIH. This suggests that binding of activation domains to TFIIH is an important aspect of transcriptional activation.

Transcription of the human T-cell lymphotropic virus type I promoter by an alpha-amanitin-resistant polymerase

The human T-lymphotropic virus type I (HTLV-I) promoter contains the structural features of a typical RNA polymerase II (pol II) template. The promoter contains a TATA box 30 bp upstream of the transcription initiation site and binding sites for several pol II transcription factors, and long poly(A)+ RNA is synthesized from the integrated HTLV-I proviral DNA in vivo. Consistent with these characteristics, HTLV-I transcription activity was reconstituted in vitro by using TATA-binding protein, TFIIA, recombinant TFIIB, TFIIE, and TFIIF, TFIIH, and pol II. Transcription of the HTLV-I promoter in the reconstituted system requires RNA pol II. In HeLa whole cell extracts, however, the HTLV-I long terminal repeat also contains an overlapping transcription unit (OTU). HTLV-I OTU transcription is initiated at the same nucleotide site as the RNA isolated from the HTLV-I-infected cell line MT-2 but was not inhibited by the presence of alpha-amanitin at concentrations which inhibited the adenovirus major late pol II promoter (6 micrograms/ml). HTLV-I transcription was inhibited when higher concentrations of alpha-amanitin (60 micrograms/ml) were used, in the range of a typical pol III promoter (VA-I). Neutralization and depletion experiments with three distinct pol II antibodies demonstrate that RNA pol II is not required for HTLV-I OTU transcription. Antibodies to basal transcription factors TATA-binding protein and TFIIB, but not TFIIIC, inhibited HTLV-I OTU transcription. These observations suggest that the HTLV-I long terminal repeat contains overlapping promoters, a typical pol II promoter and a unique pol III promoter which requires a distinct set of transcription factors.

Binding of basal transcription factor TFIIH to the acidic activation domains of VP16 and p53

Acidic transcriptional activation domains function well in both yeast and mammalian cells, and some have been shown to bind the general transcription factors TFIID and TFIIB. We now show that two acidic transactivators, herpes simplex virus VP16 and human p53, directly interact with the multisubunit human general transcription factor TFIIH and its Saccharomyces cerevisiae counterpart, factor b. The VP16- and p53-binding domains in these factors lie in the p62 subunit of TFIIH and in the homologous subunit, TFB1, of factor b. Point mutations in VP16 that reduce its transactivation activity in both yeast and mammalian cells weaken its binding to both yeast and human TFIIH. This suggests that binding of activation domains to TFIIH is an important aspect of transcriptional activation.

Transcriptional activity of transcription factor IIE is dependent on zinc binding

The functions of individual basal transcription factors during the formation of an initiation complex by RNA polymerase II remain largely unknown. Transcription factor IIE (TFIIE) has recently been shown to bind to multiple targets in the initiation complex. To assess the role of zinc binding in basal transcription, we have mutated the predicted zinc-finger domain of human TFIIE. Atomic absorption spectroscopy using purified recombinant proteins revealed that the large subunit, TFIIE-56, is indeed a zinc-binding protein. Mutation of a cysteine residue in the putative zinc-finger domain abolished zinc binding. Moreover, mutant TFIIE-56 failed to support reconstituted basal transcription in vitro, suggesting that zinc binding is required for TFIIE function. However, gel-filtration experiments and protein affinity experiments suggest that mutant TFIIE-56 forms a stable heterotetramer with the small subunit, TFIIE-34, that is similar to wild type. Interestingly, gel mobility shift experiments reveal that loss of transcriptional activity by mutant TFIIE is correlated with its inability to stably assemble into the transcription complex. These findings establish that zinc binding by TFIIE may help form a specific structure that is required for stable entry into the transcription complex.

The cardinal principle of like attracting like generates many ubiquitous oligopeptides shared by divergent proteins

Actual protein amino acid sequences are very different from random assemblages of 20 varieties of amino acids. The separate survey of 20 unrelated proteins in two steps that included eight of the 18 discussed in this paper, revealed that at the level of 5000 total residues, one out of every 32 tetrapeptides appeared in two or more identical copies, whereas at the level of 10,000 total residues, the frequency was elevated to one out of every 29. It would thus appear that only 60,000 or so, out of the possible 160,000 (20(4)) varieties of tetrapeptides, are regularly used by all proteins. These shall be defined as ubiquitous tetrapeptides. Those tetrapeptides occasionally found to be stray which did not belong to the above group of 60,000 must have been generated by new mutations. Thus, they are expected to return to the group by subsequent mutations. The above ubiquity is due to the cardinal principle of protein construction which is like attracting like. On the average, 28% of each residue is devoted to the formation of homodipeptides such as Leu-Leu, Asn-Asn and Trp-Trp. Consequently, homo-oligopeptides, pentapeptidic and longer, are readily found in two or more proteins unrelated to each other. The next in line among the ubiquitous oligopeptides are those made of similar residues. They usually contain palindromic cores such as Leu-Val-Leu, Ala-Gly-Ala and Lys-Arg-Lys.(ABSTRACT TRUNCATED AT 250 WORDS)

Transcription factors IIE and IIH and ATP hydrolysis direct promoter clearance by RNA polymerase II

Using a defined RNA polymerase II (pol II) transcription system, we have investigated the roles of basal factors at discrete stages during the transcription cycle (e.g., initiation, promoter clearance, and transcript elongation). Abortive initiation assays revealed that TATA-binding protein, transcription factors TFIIB and TFIIF, and pol II were necessary and sufficient to form functional initiation complexes on both linear and supercoiled templates. By contrast, TFIIE, TFIIH, and ATP hydrolysis were additionally required during promoter clearance from linear templates, while negative supercoiling obviated the need for these auxiliary factors. Furthermore, TFIIE, TFIIH, and supercoiling were not required during elongation. Our results suggest a role for TFIIH-associated helicase activity or supercoiling during promoter clearance rather than open complex formation. These results establish abortive initiation as a useful assay for studying functional initiation complex formation in defined eukaryotic transcription systems and provide a framework for investigating regulation at different stages of the eukaryotic transcription cycle.

Transcription factor IIE binds preferentially to RNA polymerase IIa and recruits TFIIH: a model for promoter clearance

The basal factor TFIIE is an important component of the RNA polymerase II transcription machinery. In our efforts to determine the role of TFIIE in the transcription process, we have begun to define the interactions between TFIIE and other basal transcription factors. Here we report that TFIIE binds selectively to the nonphosphorylated form of RNA polymerase II (IIa) and that this interaction is mediated by the 56-kD subunit of TFIIE. Additional binding studies reveal that TFII can interact with TBP as well as TFIID and that this interaction is mediated primarily via the 56-kD subunit. Our studies indicate that TFIIE also interacts with both subunits of TFIIF and with TFIIH, a multisubunit basal factor reported to catalyze RNA polymerase II CTD phosphorylation. Protein affinity assays demonstrate that TFIIE binds directly to ERCC-3, a DNA repair protein associated with TFIIH. More importantly, TFIIE affinity resin can selectively isolate transcriptionally competent TFIIH from a partially purified preparation and thereby may recruit TFIIH to the transcription complex in vivo. These multiple interactions between TFIIE, Pol II and TFIIH support a model in which TFIIE plays a role in promoter clearance as well as in the recruitment of proteins required for transcription-coupled DNA repair.