Functional dissection of the B" component of RNA polymerase III transcription factor IIIB: a scaffolding protein with multiple roles in assembly and initiation of transcription

Comparative analysis on bioactive compounds and antioxidant activity of Algerian fenugreek (Trigonella foenum-graecum L.) and Syrian cumin (Cuminum cyminum L.) seeds

Introduction: Natural products represent a gold mine for scientists looking for compounds for the treatment of health problems and diseases with their different biological and pharmacological activities. However, recent research is focused on finding natural sources of antioxidants.

Objective: The objective of current research was to determine the phytochemical profile of Algerian fenu-greek (Trigonella foenum-graecum L.), and Syrian cumin (Cuminum cyminum L.) seeds in order to characterize their phenolic compounds and to determine their antioxidant activities.

Methods: Total phenolic, flavonoids, condensed and hydrolysable tannins contents were quantified using Folin-Ciocalteu, aluminium chloride, vanillin and ferric chloride methods, respectively. Phenolic compounds were identified by HPLC method and antioxidant activity was measured using DPPH assay.

Results: The higher amounts of total phenolic compounds, flavonoids, condensed and hydrolysable tannins were given by fenugreek. Results of HPLC analysis of our plants showed that eight phytochemical compounds were found in cumin extract, and seven molecules in fenugreek extract. Moreover, fenugreek possessed higher antioxidant activity.

Conclusion: This study confirmed that our plants are a good source of phenolic contents and possess a high antioxidant activity.

Structural visualization of RNA polymerase III transcription machineries

RNA polymerase III (Pol III) transcription initiation requires the action of the transcription factor IIIB (TFIIIB) and is highly regulated. Here, we determine the structures of Pol III pre-initiation complexes (PICs) using single particle cryo-electron microscopy (cryo-EM). We observe stable Pol III-TFIIIB complexes using nucleic acid scaffolds mimicking various functional states, in which TFIIIB tightly encircles the upstream promoter DNA. There is an intricate interaction between TFIIIB and Pol III, which stabilizes the winged-helix domains of the C34 subunit of Pol III over the active site cleft. The architecture of Pol III PIC more resembles that of the Pol II PIC than the Pol I PIC. In addition, we also obtain a 3D reconstruction of Pol III in complex with TFIIIB using the elongation complex (EC) scaffold, shedding light on the mechanism of facilitated recycling of Pol III prior to transcription re-initiation.

Molecular mechanism of promoter opening by RNA polymerase III

RNA polymerase III (Pol III) assembles together with transcription factor IIIB (TFIIIB) on different promoter types to initiate the transcription of small, structured RNAs. Here, we present structures of Pol III pre-initiation complexes comprising the 17-subunit Pol III and hetero-trimeric transcription factor TFIIIB with subunits TATA-binding protein (TBP), B-related factor 1 (Brf1) and B double prime 1 (Bdp1) bound to a natural promoter in different functional states. Electron cryo-microscopy (cryo-EM) reconstructions varying from 3.7 Å to 5.5 Å resolution include two early intermediates in which the DNA duplex is closed, an open DNA complex and an initially transcribing complex with RNA in the active site. Our structures reveal an extremely tight and multivalent interaction of TFIIIB with promoter DNA and explain how TFIIIB recruits Pol III. TFIIIB and Pol III subunit C37 together activate the intrinsic transcription factor-like activity of the Pol III-specific heterotrimer to initiate melting of double-stranded DNA in a mechanism similar as used in the Pol II system.

Molecular mechanisms of Bdp1 in TFIIIB assembly and RNA polymerase III transcription initiation

Initiation of gene transcription by RNA polymerase (Pol) III requires the activity of TFIIIB, a complex formed by Brf1 (or Brf2), TBP (TATA-binding protein), and Bdp1. TFIIIB is required for recruitment of Pol III and to promote the transition from a closed to an open Pol III pre-initiation complex, a process dependent on the activity of the Bdp1 subunit. Here, we present a crystal structure of a Brf2-TBP-Bdp1 complex bound to DNA at 2.7 Å resolution, integrated with single-molecule FRET analysis and in vitro biochemical assays. Our study provides a structural insight on how Bdp1 is assembled into TFIIIB complexes, reveals structural and functional similarities between Bdp1 and Pol II factors TFIIA and TFIIF, and unravels essential interactions with DNA and with the upstream factor SNAPc. Furthermore, our data support the idea of a concerted mechanism involving TFIIIB and RNA polymerase III subunits for the closed to open pre-initiation complex transition.Transcription initiation by RNA polymerase III requires TFIIIB, a complex formed by Brf1/Brf2, TBP and Bdp1. Here, the authors describe the crystal structure of a Brf2-TBP-Bdp1 complex bound to a DNA promoter and characterize the role of Bdp1 in TFIIIB assembly and pre-initiation complex formation.

A Region of Bdp1 Necessary for Transcription Initiation That Is Located within the RNA Polymerase III Active Site Cleft

The RNA polymerase III (Pol III)-specific transcription factor Bdp1 is crucial to Pol III recruitment and promoter opening in transcription initiation, yet structural information is sparse. To examine its protein-binding targets within the preinitiation complex at the residue level, photoreactive amino acids were introduced into Saccharomyces cerevisiae Bdp1. Mutations within the highly conserved SANT domain cross-linked to the transcription factor IIB (TFIIB)-related transcription factor Brf1, consistent with the findings of previous studies. In addition, we identified an essential N-terminal region that cross-linked with the Pol III catalytic subunit C128 as well as Brf1. Closer examination revealed that this region interacted with the C128 N-terminal region, the N-terminal half of Brf1, and the C-terminal domain of the C37 subunit, together positioning this region within the active site cleft of the preinitiation complex. With our functional data, our analyses identified an essential region of Bdp1 that is positioned within the active site cleft of Pol III and necessary for transcription initiation.

Mapping the protein interaction network for TFIIB-related factor Brf1 in the RNA polymerase III preinitiation complex

TFIIB-related factor Brf1 is essential for RNA polymerase (Pol) III recruitment and open-promoter formation in transcription initiation. We site specifically incorporated a nonnatural amino acid cross-linker into Brf1 to map its protein interaction targets in the preinitiation complex (PIC). Our cross-linking analysis in the N-terminal domain of Brf1 indicated a pattern of multiple protein interactions reminiscent of TFIIB in the Pol active-site cleft. In addition to the TFIIB-like protein interactions, the Brf1 cyclin repeat subdomain is in contact with the Pol III-specific C34 subunit. With site-directed hydroxyl radical probing, we further revealed the binding between Brf1 cyclin repeats and the highly conserved region connecting C34 winged-helix domains 2 and 3. In contrast to the N-terminal domain of Brf1, the C-terminal domain contains extensive binding sites for TBP and Bdp1 to hold together the TFIIIB complex on the promoter. Overall, the domain architecture of the PIC derived from our cross-linking data explains how individual structural subdomains of Brf1 integrate the protein network from the Pol III active center to the promoter for transcription initiation.

Genomic insights of protein arginine methyltransferase Hmt1 binding reveals novel regulatory functions

Background

Protein arginine methylation is a post-translational modification involved in important biological processes such as transcription and RNA processing. This modification is catalyzed by both type I and II protein arginine methyltransferases (PRMTs). One of the most conserved type I PRMTs is PRMT1, the homolog of which is Hmt1 in Saccharomyces cerevisiae. Hmt1 has been shown to play a role in various gene expression steps, such as promoting the dynamics of messenger ribonucleoprotein particle (mRNP) biogenesis, pre-mRNA splicing, and silencing of chromatin. To determine the full extent of Hmt1’s involvement during gene expression, we carried out a genome-wide location analysis for Hmt1.

Results

A comprehensive genome-wide binding profile for Hmt1 was obtained by ChIP-chip using NimbleGen high-resolution tiling microarrays. Of the approximately 1000 Hmt1-binding sites found, the majority fall within or proximal to an ORF. Different occupancy patterns of Hmt1 across genes with different transcriptional rates were found. Interestingly, Hmt1 occupancy is found at a number of other genomic features such as tRNA and snoRNA genes, thereby implicating a regulatory role in the biogenesis of these non-coding RNAs. RNA hybridization analysis shows that Hmt1 loss-of-function mutants display higher steady-state tRNA abundance relative to the wild-type. Co-immunoprecipitation studies demonstrate that Hmt1 interacts with the TFIIIB component Bdp1, suggesting a mechanism for Hmt1 in modulating RNA Pol III transcription to regulate tRNA production.

Conclusions

The genome-wide binding profile of Hmt1 reveals multiple potential new roles for Hmt1 in the control of eukaryotic gene expression, especially in the realm of non-coding RNAs. The data obtained here will provide an important blueprint for future mechanistic studies on the described occupancy relationship for genomic features bound by Hmt1.

Without a license, or accidents waiting to happen

This is a memoir of circumstances that have shaped my life as a scientist, some of the questions that have excited my interest, and some of the people with whom I have shared that pursuit. I was introduced to transcription soon after the discovery of RNA polymerase and have been fascinated by questions relating to gene regulation since that time. My account touches on early experiments dealing with the ability of RNA polymerase to selectively transcribe its DNA template. Temporal programs of transcription that control the multiplication cycles of viruses (phages) and the precise mechanisms generating this regulation have been a continuing source of fascination and new challenges. A longtime interest in eukaryotic RNA polymerase III has centered on yeast and on the enumeration and properties of its transcription initiation factors, the architecture of its promoter complexes, and the mechanism of transcriptional initiation. These areas of research are widely regarded as separate, but to my thinking they have posed similar questions, and I have been unwilling or unable to abandon either one for the other. An additional interest in archaeal transcription can be seen as stemming naturally from this point of view.

Mapping the Principal Interaction Site of the Brf1 and Bdp1 Subunits of Saccharomyces cerevisiae TFIIIB

The Brf1 subunit of the central RNA polymerase (pol) III transcription initiation factor TFIIIB is bipartite; its N-terminal TFIIB-related half is principally responsible for recruiting pol III to the promoter and for promoter opening near the transcriptional start site, whereas its pol III-specific C-terminal half contributes most of the affinities that hold the three subunits of TFIIIB together. Here, the principal attachment site of Brf1 for the Bdp1 subunit of TFIIIB has been mapped by a combination of structure-informed, site-directed mutagenesis and photochemical protein-DNA cross-linking. A 66-amino acid segment of Brf1 is shown to serve as a two-sided adhesive surface, with the side chains projecting away from its extended interface with TATA-binding protein anchoring Bdp1 binding. An extensive collection of N-terminal, C-terminal, and internal deletion proteins has been used to demarcate the interacting Bdp1 domain to a 66-amino acid segment that includes the SANT domain of this subunit and is phylogenetically the most conserved region of Bdp1.

Nhp6 is a transcriptional initiation fidelity factor for RNA polymerase III transcription in vitro and in vivo

The binding of the RNA polymerase III (pol III) transcription factor TFIIIC to the box A intragenic promoter element of tRNA genes specifies the placement of TFIIIB on upstream-lying DNA. In turn, TFIIIB recruits pol III to the promoter and specifies transcription initiating 17-19 base pairs upstream of box A. The resolution of the pol III transcription apparatus into recombinant TFIIIB, highly purified TFIIIC, and pol III is accompanied by a loss of precision in specifying where transcription initiation occurs due to heterogeneous placement of TFIIIB. In this paper we show that Nhp6a, an abundant high mobility group B (HMGB) family, non-sequence-specific DNA-binding protein in Saccharomyces cerevisiae restores transcriptional initiation fidelity to this highly purified in vitro system. Restoration of initiation fidelity requires the presence of Nhp6a prior to TFIIIB-DNA complex formation. Chemical nuclease footprinting of TFIIIC- and TFIIIB-TFIIIC-DNA complexes reveals that Nhp6a markedly alters the TFIIIC footprint over box A and reduces the size of the TFIIIB footprint on upstream DNA sequence. Analyses of unprocessed tRNAs from yeast lacking Nhp6a and its closely related paralogue Nhp6b demonstrate that Nhp6 is required for transcriptional initiation fidelity of some but not all tRNA genes, in vivo.

TFIIIB subunit Bdp1p is required for periodic integration of the Ty1 retrotransposon and targeting of Isw2p to S. cerevisiae tDNAs

Retrotransposons are RNA elements that reverse transcribe their RNA genomes and make a cDNA copy that is inserted back into a new genomic location by the element-encoded integrase protein. Ty1 is a long terminal repeat (LTR) retrotransposon in Saccharomyces cerevisiae that inserts into an approximately 700-bp integration window upstream of tRNA genes with a periodicity of approximately 80 bp. ATP-dependent chromatin remodeling by Isw2 upstream of tRNA genes leads to changes in chromatin structure and Ty1 integration site selection. We show that the N terminus of Bdp1p, a component of the RNA polymerase III transcription factor TFIIIB, is required for periodic integration of Ty1 into the integration window. Deletion of the Bdp1p N terminus and mutation of ISW2 result in similar disruption of nucleosome positioning upstream of some tRNA genes, and the N-terminal domain of Bdp1p is required for targeting of Isw2 complex to tRNA genes. This study provides the first example for recruitment of an ATP-dependent chromatin-remodeling factor by a general transcription factor in vivo.

Genome-wide location of yeast RNA polymerase III transcription machinery

RNA polymerase III (Pol III) transcribes a large set of genes encoding small untranslated RNAs like tRNAs, 5S rRNA, U6 snRNA or RPR1 RNA. To get a global view of class III (Pol III-transcribed) genes, the distribution of essential components of Pol III, TFIIIC and TFIIIB was mapped across the yeast genome. During active growth, most class III genes and few additional loci were targeted by TFIIIC, TFIIIB and Pol III, indicating that they were transcriptionally active. SNR52, which encodes a snoRNA, was identified as a new class III gene. During the late growth phase, TFIIIC remained bound to most class III genes while the recruitment of Pol III and, to a lesser extent, of TFIIIB was down regulated. This study fixes a reasonable upper bound to the number of class III genes in yeast and points to a global regulation at the level of Pol III and TFIIIB recruitment.

A gene-specific effect of an internal deletion in the Bdp1 subunit of the RNA polymerase III transcription initiation factor TFIIIB

The Saccharomyces cerevisiae RPR1 gene encodes the RNA subunit of its RNase P, which processes RNA polymerase (pol) III primary transcripts. RPR1, which is transcribed by pol III, has been isolated as a multicopy suppressor of a specific small internal deletion (amino acids 253-269) in the Bdp1 subunit of transcription factor TFIIIB, the core pol III transcription factor. The selective effect of this Bdp1 deletion on RPR1 transcription has been analyzed in vitro. It is shown that TFIIIC-dependent assembly of TFIIIB on the RPR1 promoter is specifically sensitive to this Bdp1 deletion, leading to gene-specifically defective single-round and multiple-round transcription.

Mutational and functional analysis of a segment of the sigma family bacteriophage T4 late promoter recognition protein gp55

Bacteriophage T4 late promoters, which consist of a simple 8-base pair TATA box, are recognized by the gene 55 protein (gp55), a small, highly diverged member of the sigma family proteins that replaces sigma(70) during the final phase of the T4 multiplication cycle. A 16-amino acid segment of gp55 that is proposed to be homologous to the sigma(70) region 2.2 has been subjected to alanine scanning and other mutagenesis. The corresponding proteins have been examined in vitro for binding to Escherichia coli RNA polymerase core enzyme and for the ability to generate accurately initiating basal as well as sliding clamp-activated T4 late transcription. Mutations in the amino acid 68-83 segment of gp55 generate a wide range of effects on these functions. The changes are interpreted in terms of the multiple steps of involvement of gp55, like other sigma proteins, in transcription. Effects of mutations on RNA polymerase core binding are consistent with the previously proposed homology of amino acids 68-82 of gp55 with sigma(70) region 2.2 and the recently determined structures of the Thermus thermophilus and Thermus aquaticus sigma(70)-RNA polymerase holoenzymes.

A single-stranded promoter for RNA polymerase III

Single strands of DNA serve, in rare instances, as promoters for transcription; duplex DNA promoters with individual strands that also have a promoter capacityfunction have not been described. We show that the nontranscribed strand of the Saccharomyces cerevisiae U6 snRNA gene directs transcription initiation factor IIIB-requiring and accurately initiating transcription by RNA polymerase III. The nontranscribed strand promoter is much more extended than its duplex DNA counterpart, comprising the U6 gene TATA box, a downstream T(7) tract, and an upstream-lying segment. A requirement for placement of the 3' end of the transcribed (template) strand within the confines of the transcription bubble is seen as indicating that the nontranscribed strand provides a scaffold for RNA polymerase recruitment but is deficient at a subsequent step of transcription initiation factor IIIB's direct involvement in promoter opening.

Effects of DNA strand breaks on transcription by RNA polymerase III: insights into the role of TFIIIB and the polarity of promoter opening

Certain deletion mutants of the Brf1 and Bdp1 subunits of transcription factor (TF) IIIB retain the ability to recruit RNA polymerase (pol) III to its promoters, but fail to support promoter opening: deletions within an internal Bdp1 segment interfere with initiation of DNA strand separation, and an N-terminal Brf1 deletion blocks propagation of promoter opening past the transcriptional start site. The ability of DNA strand breaks to restore pol III transcription activity to these defective TFIIIB assemblies has been analyzed using U6 snRNA gene constructs. Breaks in a 21 bp segment spanning the transcriptional start rescue transcription in DNA strand-specific and subunit/mutation-specific patterns. A cluster of Bdp1 internal deletions also reverses the inactivation of transcription with wild-type TFIIIB generated by certain transcribed (template) strand breaks near the transcriptional start site. A structure-based model and topological considerations interpret these observations, explain how Bdp1 and Brf1 help to enforce the general upstream--> downstream polarity of promoter opening and specify requirements for polarity reversal.

A gain-of-function mutation in the second tetratricopeptide repeat of TFIIIC131 relieves autoinhibition of Brf1 binding

The interaction between the tetratricopeptide repeat (TPR)-containing subunit of TFIIIC, TFIIIC131, and the TFIIB-related factor Brf1 represents a limiting step in the assembly of the RNA polymerase III (pol III) initiation factor TFIIIB. This assembly reaction is facilitated by dominant mutations that map in and around TPR2. Structural modeling of TPR1 to TPR3 from TFIIIC131 shows that one such mutation, PCF1-2, alters a residue in the ligand-binding groove of the TPR superhelix whereas another mutation, PCF1-1, changes a surface-accessible residue on the back side of the TPR superhelix. In this work, we show that the PCF1-1 mutation (H190Y) increases the binding affinity for Brf1, but does not affect the binding affinity for Bdp1, in the TFIIIC-dependent assembly of TFIIIB. Interestingly, binding studies with TFIIIC131 fragments indicate that Brf1 does not interact directly at the site of the PCF1-1 mutation. Rather, the data suggest that the mutation overcomes the previously documented autoinhibition of Brf1 binding. These findings together with the results from site-directed mutagenesis support the hypothesis that gain-of-function mutations at amino acid 190 in TPR2 stabilize an alternative conformation of TFIIIC131 that promotes its interaction with Brf1.

Mutational analysis of the transcription factor IIIB-DNA target of Ty3 retroelement integration

The Ty3 retrovirus-like element inserts preferentially at the transcription initiation sites of genes transcribed by RNA polymerase III. The requirements for transcription factor (TF) IIIC and TFIIIB in Ty3 integration into the two initiation sites of the U6 gene carried on pU6LboxB were previously examined. Ty3 integrates at low but detectable frequencies in the presence of TFIIIB subunits Brf1 and TATA-binding protein. Integration increases in the presence of the third subunit, Bdp1. TFIIIC is not essential, but the presence of TFIIIC specifies an orientation of TFIIIB for transcriptional initiation and directs integration to the U6 gene-proximal initiation site. In the current study, recombinant wild type TATA-binding protein, wild type and mutant Brf1, and Bdp1 proteins and highly purified TFIIIC were used to investigate the roles of specific protein domains in Ty3 integration. The amino-terminal half of Brf1, which contains a TFIIB-like repeat, contributed more strongly than the carboxyl-terminal half of Brf1 to Ty3 targeting. Each half of Bdp1 split at amino acid 352 enhanced integration. In the presence of TFIIIB and TFIIIC, the pattern of integration extended downstream by several base pairs compared with the pattern observed in vitro in the absence of TFIIIC and in vivo, suggesting that TFIIIC may not be present on genes targeted by Ty3 in vivo. Mutations in Bdp1 that affect its interaction with TFIIIC resulted in TFIIIC-independent patterns of Ty3 integration. Brf1 zinc ribbon and Bdp1 internal deletion mutants that are competent for polymerase III recruitment but defective in promoter opening were competent for Ty3 integration irrespective of the state of DNA supercoiling. These results extend the similarities between the TFIIIB domains required for transcription and Ty3 integration and also reveal requirements that are specific to transcription.

Essential roles of Bdp1, a subunit of RNA polymerase III initiation factor TFIIIB, in transcription and tRNA processing

The essential Saccharomyces cerevisiae gene BDP1 encodes a subunit of RNA polymerase III (Pol III) transcription factor (TFIIIB); TATA box binding protein (TBP) and Brf1 are the other subunits of this three-protein complex. Deletion analysis defined three segments of Bdp1 that are essential for viability. A central segment, comprising amino acids 327 to 353, was found to be dispensable, and cells making Bdp1 that was split within this segment, at amino acid 352, are viable. Suppression of bdp1 conditional viability by overexpressing SPT15 and BRF1 identified functional interactions of specific Bdp1 segments with TBP and Brf1, respectively. A Bdp1 deletion near essential segment I was synthetically lethal with overexpression of PCF1-1, a dominant gain-of-function mutation in the second tetracopeptide repeat motif (out of 11) of the Tfc4 (tau(131)) subunit of TFIIIC. The analysis also identifies a connection between Bdp1 and posttranscriptional processing of Pol III transcripts. Yeast genomic library screening identified RPR1 as the specific overexpression suppressor of very slow growth at 37 degrees C due to deletion of Bdp1 amino acids 253 to 269. RPR1 RNA, a Pol III transcript, is the RNA subunit of RNase P, which trims pre-tRNA transcript 5' ends. Maturation of tRNA was found to be aberrant in bdp1-Delta 253-269 cells, and RPR1 transcription with the highly resolved Pol III transcription system in vitro was also diminished when recombinant Bdp1 Delta 253-269 replaced wild-type Bdp1. Physical interaction of RNase P with Bdp1 was demonstrated by coimmunoprecipitation and pull-down assays.

Multiple roles of the tau131 subunit of yeast transcription factor IIIC (TFIIIC) in TFIIIB assembly

Yeast transcription factor IIIC (TFIIIC) plays a key role in assembling the transcription initiation factor TFIIIB on class III genes after TFIIIC-DNA binding. The second largest subunit of TFIIIC, tau131, is thought to initiate TFIIIB assembly by interacting with Brf1/TFIIIB70. In this work, we have analyzed a TFIIIC mutant (tau131-DeltaTPR2) harboring a deletion in tau131 removing the second of its 11 tetratricopeptide repeats. Remarkably, this thermosensitive mutation was selectively suppressed in vivo by overexpression of B"/TFIIIB90, but not Brf1 or TATA-binding protein. In vitro, the mutant factor preincubated at restrictive temperature bound DNA efficiently but lost transcription factor activity. The in vitro transcription defect was abolished at high concentrations of B" but not Brf1. Copurification experiments of baculovirus-expressed proteins confirmed a direct physical interaction between tau131 and B". tau131, therefore, appears to be involved in the recruitment of both Brf1 and B".

The S. cerevisiae SET3 complex includes two histone deacetylases, Hos2 and Hst1, and is a meiotic-specific repressor of the sporulation gene program

Set3 is one of two proteins in the yeast Saccharomyces cerevisiae that, like Drosophila Trithorax, contains both SET and PHD domains. We found that Set3 forms a single complex, Set3C, with Snt1, YIL112w, Sif2, Cpr1, and two putative histone deacetylases, Hos2 and NAD-dependent Hst1. Set3C includes NAD-dependent and independent deacetylase activities when assayed in vitro. Homology searches suggest that Set3C is the yeast analog of the mammalian HDAC3/SMRT complex. Set3C represses genes in early/middle of the yeast sporulation program, including the key meiotic regulators ime2 and ndt80. Whereas Hos2 is only found in Set3C, Hst1 is also present in a complex with Sum1, supporting previous characterizations of Hst1 and Sum1 as repressors of middle sporulation genes during vegetative growth. However, Hst1 is not required for meiotic repression by Set3C, thus implying that Set3C (-Hst1) and not Hst1-Sum1, is the meiotic-specific repressor of early/middle sporulation genes.

B"-associated factor(s) involved in RNA polymerase III preinitiation complex formation and start-site selection

The TFIIIB transcription factor is the central component of the RNA polymerase III transcriptional machinery. In yeast, this factor is composed of three essential polypeptides TBP, TFIIIB70 and TFIIIB90, that are sufficient as recombinant proteins, together with TFIIIC, to promote accurate transcription in vitro. Here we show that a partially purified fraction, named B", that contains the TFIIIB90 subunit, displays properties distinct from recombinant TFIIIB90. This fraction contains at least a component that interacts with DNA*TFIIIC complexes, either alone or in combination with TFIIIB90, and increases the resistance of the complexes to heparin treatment. In addition, primer extension and single round transcriptions experiment reveal a different start-site selection pattern directed by B" or rTFIIIB90. In mixing experiments, we show that an activity in B", distinct from TFIIIB90, can promote transcription initiation at the +1 site without affecting the rate of preinitiation complex formation. Our data suggest the existence of at least one new component that participates in preinitiation complex formation and influences start-site selection by RNA polymerase III.

Kinetic trapping of DNA by transcription factor IIIB

High levels of RNA polymerase III gene transcription are achieved by facilitated recycling of the polymerase on transcription factor IIIB (TFIIIB)-DNA complexes that are stable through multiple rounds of initiation. TFIIIB-DNA complexes in yeast comprise the TATA-binding protein (TBP), the TFIIB-related factor TFIIIB70, and TFIIIB90. The high stability of the TFIIIB-DNA complex is conferred by TFIIIB90 binding to TFIIIB70-TBP-DNA complexes. This stability is thought to result from compound bends introduced in the DNA by TBP and TFIIIB90 and by protein-protein interactions that obstruct DNA dissociation. Here we present biochemical evidence that the high stability of TFIIIB-DNA complexes results from kinetic trapping of the DNA. Thermodynamic analysis shows that the free energies of formation of TFIIIB70-TBP-DNA (DeltaG degrees = -12.10 +/- 0.12 kcal/mol) and TFIIIB-DNA (DeltaG degrees = -11.90 +/- 0.14 kcal/mol) complexes are equivalent whereas a kinetic analysis shows that the half-lives of these complexes (46 +/- 3 min and 95 +/- 6 min, respectively) differ significantly. The differential stability of these isoenergetic complexes demonstrates that TFIIIB90 binding energy is used to drive conformational changes and increase the barrier to complex dissociation.

Comparison of the RNA polymerase III transcription machinery in Schizosaccharomyces pombe, Saccharomyces cerevisiae and human

Multi-subunit transcription factors (TF) direct RNA polymerase (pol) III to synthesize a variety of essential small transcripts such as tRNAs, 5S rRNA and U6 snRNA. Use by pol III of both TATA-less and TATA-containing promoters, together with progress in the Saccharomyces cerevisiae and human systems towards elucidating the mechanisms of actions of the pol III TFs, provides a paradigm for eukaryotic gene transcription. Human and S.cerevisiae pol III components reveal good general agreement in the arrangement of orthologous TFs that are distributed along tRNA gene control elements, beginning upstream of the transcription initiation site and extending through the 3' terminator element, although some TF subunits have diverged beyond recognition. For this review we have surveyed the Schizosaccharomyces pombe database and identified 26 subunits of pol III and associated TFs that would appear to represent the complete core set of the pol III machinery. We also compile data that indicate in vivo expression and/or function of 18 of the fission yeast proteins. A high degree of homology occurs in pol III, TFIIIB, TFIIIA and the three initiation-related subunits of TFIIIC that are associated with the proximal promoter element, while markedly less homology is apparent in the downstream TFIIIC subunits. The idea that the divergence in downstream TFIIIC subunits is associated with differences in pol III termination-related mechanisms that have been noted in the yeast and human systems but not reviewed previously is also considered.

The RNA polymerase III transcription initiation factor TFIIIB participates in two steps of promoter opening

Evidence for post-recruitment functions of yeast transcription factor (TF)IIIB in initiation of transcription was first provided by the properties of TFIIIB-RNA polymerase III-promoter complexes assembled with deletion mutants of its Brf and B" subunits that are transcriptionally inactive because they fail to open the promoter. The experiments presented here show that these defects can be repaired by unpairing short (3 or 5 bp) DNA segments spanning the transcription bubble of the open promoter complex. Analysis of this suppression phenomenon indicates that TFIIIB participates in two steps of promoter opening by RNA polymerase III that are comparable to the successive steps of promoter opening by bacterial RNA polymerase holoenzyme. B" deletions between amino acids 355 and 421 interfere with the initiating step of DNA strand separation at the upstream end of the transcription bubble. Removing an N-terminal domain of Brf interferes with downstream propagation of the transcription bubble to and beyond the transcriptional start site.

Different human TFIIIB activities direct RNA polymerase III transcription from TATA-containing and TATA-less promoters

Transcription initiation at RNA polymerase III promoters requires transcription factor IIIB (TFIIIB), an activity that binds to RNA polymerase III promoters, generally through protein-protein contacts with DNA binding factors, and directly recruits RNA polymerase III. Saccharomyces cerevisiae TFIIIB is a complex of three subunits, TBP, the TFIIB-related factor BRF, and the more loosely associated polypeptide beta("). Although human homologs for two of the TFIIIB subunits, the TATA box-binding protein TBP and the TFIIB-related factor BRF, have been characterized, a human homolog of yeast B(") has not been described. Moreover, human BRF, unlike yeast BRF, is not universally required for RNA polymerase III transcription. In particular, it is not involved in transcription from the small nuclear RNA (snRNA)-type, TATA-containing, RNA polymerase III promoters. Here, we characterize two novel activities, a human homolog of yeast B("), which is required for transcription of both TATA-less and snRNA-type RNA polymerase III promoters, and a factor equally related to human BRF and TFIIB, designated BRFU, which is specifically required for transcription of snRNA-type RNA polymerase III promoters. Together, these results contribute to the definition of the basal RNA polymerase III transcription machinery and show that two types of TFIIIB activities, with specificities for different classes of RNA polymerase III promoters, have evolved in human cells.

Survey and summary: transcription by RNA polymerases I and III

The task of transcribing nuclear genes is shared between three RNA polymerases in eukaryotes: RNA polymerase (pol) I synthesizes the large rRNA, pol II synthesizes mRNA and pol III synthesizes tRNA and 5S rRNA. Although pol II has received most attention, pol I and pol III are together responsible for the bulk of transcriptional activity. This survey will summarise what is known about the process of transcription by pol I and pol III, how it happens and the proteins involved. Attention will be drawn to the similarities between the three nuclear RNA polymerase systems and also to their differences.

TATA-Binding protein-TATA interaction is a key determinant of differential transcription of silkworm constitutive and silk gland-specific tRNA(Ala) genes

We have investigated the contribution of specific TATA-binding protein (TBP)-TATA interactions to the promoter activity of a constitutively expressed silkworm tRNA(C)(Ala) gene and have also asked whether the lack of similar interactions accounts for the low promoter activity of a silk gland-specific tRNA(SG)(Ala) gene. We compared TBP binding, TFIIIB-promoter complex stability (measured by heparin resistance), and in vitro transcriptional activity in a series of mutant tRNA(C)(Ala) promoters and found that specific TBP-TATA contacts are important for TFIIIB-promoter interaction and for transcriptional activity. Although the wild-type tRNA(C)(Ala) promoter contains two functional TBP binding sequences that overlap, the tRNA(SG)(Ala) promoter lacks any TBP binding site in the corresponding region. This feature appears to account for the inefficiency of the tRNA(SG)(Ala) promoter since provision of either of the wild-type TATA sequences derived from the tRNA(C)(Ala) promoter confers robust transcriptional activity. Transcriptional impairment of the wild-type tRNA(SG)(Ala) gene is not due to reduced incorporation of TBP into transcription complexes since both the tRNA(C)(Ala) and tRNA(SG)(Ala) promoters form transcription complexes that contain the same amount of TBP. Thus, the deleterious consequences of the lack of appropriate TBP-TATA contacts in the tRNA(SG)(Ala) promoter must come from failure to incorporate some other essential transcription factor(s) or to stabilize the complete complex in an active conformation.

Alignment of the B" subunit of RNA polymerase III transcription factor IIIB in its promoter complex

TFIIIB, the central transcription initiation factor of the eukaryotic nuclear RNA polymerase (pol) III is composed of three subunits: the TATA-binding protein; Brf, the TFIIB-related subunit; and B", the Saccharomyces cerevisiae, TFC5 gene product. The orientation of the B" subunit within the TFIIIB-DNA complex has been analyzed at two promoters by two approaches that involve site-specific photochemical protein-DNA cross-linking: a collection of B" internal and external deletion proteins has been surveyed for those deletions that alter the interaction of B" with DNA or change the orientation of B" relative to DNA; a method for regionally mapping cross-links between specific DNA sites and (32)P-end-labeled protein has also been applied. The results map an N-proximal segment of B" to the upstream end of the TFIIIB-DNA complex and amino acids 299-315 to the principal DNA-contact site, approximately 8 base pairs upstream of the TATA box. The analysis also indicates that a segment comprising amino acids 316-434 loops away from DNA, and locates the C-proximal 170 amino acids of B" downstream of the TATA box. Examination of two-cross-link products formed by DNA with adjacent and nearby photoactive nucleotides supports the conclusion that Brf and B" share an extended interface along the length of the TFIIIB-DNA complex.

The RNA polymerase III-recruiting factor TFIIIB induces a DNA bend between the TATA box and the transcriptional start site

TFIIIB, the RNA polymerase III-recruiting factor of Saccharomyces cerevisiae, may be assembled upstream of the transcriptional start site, either through the interaction of its constituent TATA-binding protein (TBP) with a strong TATA-box, or by means of the multisubunit assembly factor, TFIIIC. Missing nucleoside interference analysis of TFIIIC-dependent TFIIIB-DNA complex formation revealed enhanced complex formation at 0 degreesC when the DNA is missing nucleosides in two broad 7-10 bp regions centered around base-pairs -17 and -3 relative to the transcriptional start site; no effect of missing nucleosides was evident at 20 degreesC. The implication of these results for required DNA flexure in TFIIIC-mediated TFIIIB-DNA complex formation was pursued in a TFIIIC-independent context, using DNA with a suboptimal 6 bp TATA box (TATAAA). A unique missing nucleoside at the downstream end of the TATA box, corresponding to the position of one of two TBP-mediated DNA kinks, significantly enhances TBP-DNA complex formation. In contrast, TFIIIB displays a broad preference for missing nucleosides within an approximately 15 bp region immediately downstream of the TATA box. Consecutive mismatches (4-nt loops), either at the sites of TBP-mediated DNA kinking at both ends of the TATA box or within the identified region where missing nucleosides promote TFIIIB-DNA complex formation, also result in enhanced and specific TFIIIB assembly; 4-nt loops further downstream do not lead to preferential placement of TFIIIB. We conclude that TFIIIB induces an additional DNA deformation between the TATA box and the start site of transcription that is likely to be more extended than the sharp kinks generated by TBP.

A review of progress towards elucidating the role of protein kinase CK2 in polymerase III transcription: regulation of the TATA binding protein

We have investigated the molecular basis of the requirement for protein kinase CK2 in nuclear transcription in Saccharomyces cerevisiae. In vivo and in vitro analysis has demonstrated that CK2 is required for efficient transcription of the tRNA and 55 rRNA genes by RNA polymerase III. This suggests that a component of the pol III transcription machinery is regulated by CK2. We tested this possibility by a biochemical complementation approach in which components of the pol III transcription machinery from wild type cells were tested for their ability to rescue transcription in extract from a conditionally CK2-deficient mutant. We found that pol III transcription initiation factor IIIB (TFIIIB) fully restores transcription in CK2-deficient extract. Further in vitro studies revealed that TFIIIB must be phosphorylated to be active, that a single subunit of wild type TFIIIB, the TATA binding protein (TBP), is efficiently phosphorylated by CK2, and that recombinant TBP and a limiting amount of CK2 rescues transcription in CK2-deficient extract. We conclude that TBP is the physiological target of CK2 among the components of the pol III transcription machinery. The implications of this result are discussed in the context of previous data concerning the regulation of TFIIIB.

Abortive initiation of transcription at a hybrid promoter. An analysis of the sliding clamp activator of bacteriophage T4 late transcription, and a comparison of the sigma70 and T4 gp55 promoter recognition proteins

Bacteriophage T4 late promoters are transcribed by an RNA polymerase holoenzyme comprising the Escherichia coli core, E, the phage gene 55-encoded promoter recognition subunit, gp55, and the gene 33-encoded co-activator, gp33. Transcriptional initiation is activated by the T4 gene 45-encoded sliding clamp, which is loaded on to DNA at enhancer-like sites by its clamp-loader. Correct initiation of transcription at late promoters in basal mode requires only RNA polymerase core and gp55 (E.gp55). Dinucleotide-primed abortive initiation of basal and activated T4 late transcription has been compared. Only the trinucleotide non-productive transcript is made at a high rate; all other short transcripts are made at rates of less than one molecule per productive transcript. Gp45 increases abortive trinucleotide synthesis along with productive transcription, although the proportion of productive transcripts is also elevated. Nevertheless, this increase accounts for only a small part of the activation of T4 late transcription that is generated by its activator and co-activator. The pattern of production of short transcripts differs subtly between basal and enhanced transcription, indicating that linking the RNA polymerase with its sliding clamp activator only generates minor changes in the transition from abortive to productive RNA chain elongation. The T4 late promoter is converted to a strong sigma70 promoter by inserting an appropriate -35 promoter element. A direct comparison at such a hybrid promoter shows sigma70 and gp55 generating qualitatively and quantitative different patterns of abortive initiation at the same start site.

Functional and structural organization of Brf, the TFIIB-related component of the RNA polymerase III transcription initiation complex

Brf is the TFIIB-related component of Saccharomyces cerevisiae RNA polymerase III transcription initiation factor IIIB (TFIIIB). An extensive set of Brf fragments has been examined for the abilities to assemble the TFIIIB-DNA complex and recruit RNA polymerase III to accurately initiate transcription. The principal TFIIIB-assembly function of Brf was found to be contributed by a C-proximal segment spanning amino acids 435 to 545, while the principal transcription-directing function was contributed by a segment of its N-proximal, TFIIB-homologous half. The diverse activities of Brf were also reconstituted from combined fragments. The fragments spanning amino acids 1 to 282 and 284 to 596 were found to assemble into TFIIIB-DNA and TFIIIC-TFIIIB-DNA complexes that were very stable, transcriptionally highly active, and indistinguishable (by in vitro footprinting) from complexes formed with intact Brf. The proximities of the individual halves of split Brf to DNA were extensively mapped by photochemical cross-linking of the TFIIIB-DNA complex. We also identified sites of interaction of Brf fragments with TATA-binding protein (TBP), taking advantage of a recently completed mutational analysis of the TBP surface. The constraints established by these analyses specify a global model of the functional segments of Brf and how they fit into the structure of the TFIIIB-DNA complex.

A post-recruitment function for the RNA polymerase III transcription-initiation factor IIIB

Transcription factor (TF) IIIB, which directs RNA polymerase (pol) III to its promoters, is made up of three components: the TATA box-binding protein, the TFIIB-related Brf, and the pol III-specific B". Certain mutations in Saccharomyces cerevisiae Brf and B" retain TFIIIB transcription factor activity with supercoiled DNA but are inactive with linear duplex DNA. Further analysis shows that these inactive TFIIIB-DNA complexes bind pol III and position it appropriately over the transcriptional start site but do not form DNA strand-separated open promoter complexes. It is proposed that the normal function of TFIIIB combines pol III recruitment with an active role in a subsequent step of transcriptional initiation leading to promoter opening.

A differential response of wild type and mutant promoters to TFIIIB70 overexpression in vivo and in vitro

TFIIIB, the initiation factor for transcription by RNA polymerase III (pol III) is, in yeast, composed of three subunits: TBP, TFIIIB70/Brf1 and TFIIIB90. To determine the extent to which each of these subunits is limiting for pol III transcription, the effect of overexpressing each subunit was assessed on the expression of wild-type and promoter mutant pol III genes both in vivo and in vitro . In vivo , we find that the synthesis of wild-type pol III genes is not limited to a significant extent by the level of any TFIIIB subunit. There is, however, a two-fold increase in the synthesis of the promoter mutant gene, sup9-e A19-supS1 , in strains overexpressing TFIIIB70. The findings suggest that overexpression of TFIIIB70has a differential effect on the expression of pol III genes with strong versus weak promoters. In vitro transcription assays support this conclusion and reveal an inverse correlation between the transcriptional response to TFIIIB70overexpression and promoter strength. The individual TFIIIB subunits are nuclear by immunofluorescence and are calculated to have nuclear concentrations in the low micromolar range. In comparison, the factors are diluted 100-fold or more in whole cell extracts. This dilution accounts for the generally limiting nature of TFIIIB70in pol III gene transcription in vitro.

Polymerase (Pol) III TATA box-binding protein (TBP)-associated factor Brf binds to a surface on TBP also required for activated Pol II transcription

The TATA box-binding protein (TBP) plays an essential role in transcription by all three eukaryotic nuclear RNA polymerases, polymerases (Pol) I, II, and III. In each case, TBP interacts with class-specific TBP-associated factors (TAFs) to form class-specific transcription initiation factors. For yeast Pol III transcription, TBP associates with Brf (from TFIIB-related factor) and B", two Pol III TAFs, to form Pol III transcription factor TFIIIB. Here, we identify TBP surface residues that are required for interaction with yeast Pol III TAFs. Ninety-one human TBP surface residue mutants with radical substitutions were analyzed for the ability to form stable gel shift complexes with purified Brf and B" and for their activities for in vitro synthesis of yeast U6 snRNA. Mutations in a large positively charged epitope extending from the top (that is, on the surface opposite the DNA-facing "saddle" of TBP) and onto the side of the first TBP repeat inhibited binding to Brf (residues K181, L185, R186, E206, R231, L232, R235, K236, R239, Q242, K243, K249, and F250). A triple-mutant TBP (R231E + R235E + R239S) had greatly reduced activity for yeast U6 snRNA gene transcription while remaining active for Pol II basal transcription. Similar results were observed when selected mutations were introduced into yeast TBP at equivalent positions. A C-terminal fragment of Brf lacking the region of homology with TFIIB retains the ability to bind TBP-DNA complexes (G. Kassavetis, C. Bardeleben, A. Kumar, E. Ramirez, and E. P. Geiduschek, Mol. Cell. Biol. 17:5299-5306, 1997); the same TBP mutations reduced binding by this fragment. Mutations in TBP residues that interact with TFIIB did not affect Brf binding or U6 gene transcription. These results indicate that Brf and TFIIB interact differently with TBP. An extensively overlapping epitope on the top surface of TBP was found previously to be required for activated Pol II transcription and has been hypothesized to interact with Pol II TAFs. Our results map the surface of TBP that interacts with Brf and suggest that Pol II and Pol III TAFs interact with the same surface of TBP.

A tetratricopeptide repeat mutation in yeast transcription factor IIIC131 (TFIIIC131) facilitates recruitment of TFIIB-related factor TFIIIB70

Transcription factor IIIC (TFIIIC) plays an important role in assembling the initiation factor TFIIIB on genes transcribed by RNA polymerase III (Pol III). In Saccharomyces cerevisiae, assembly of the TFIIIB complex by promoter-bound TFIIIC is thought to be initiated by its tetratricopeptide repeat (TPR)-containing subunit, TFIIIC131, which interacts directly with the TFIIB-related factor, TFIIIB70/Brf1. In this work, we have identified 10 dominant mutations in TFIIIC131 that increase Pol III gene transcription. All of these mutations are found within a discrete 53-amino-acid region of the protein encompassing TPR2. Biochemical studies of one of the mutations (PCF1-2) show that the increase in transcription is due to an increase in the recruitment of TFIIIB70 to TFIIC-DNA. The PCF1-2 mutation does not affect the affinity of TFIIIC for DNA, and the differential in both transcription and TFIIIB complex assembly is observed at saturating levels of TFIIIB70. This indicates that mutant and wild-type TFIIIC-DNA complexes have the same affinity for TFIIIB70 and suggests that the increased recruitment of this factor is achieved by a nonequilibrium binding mechanism. A novel mechanism of activation in which the TPR mutations facilitate a conformational change in TFIIIC that is required for TFIIIB70 binding is proposed. The implications of this model for the regulation of processes involving TPR proteins are discussed.

Casein kinase II regulation of yeast TFIIIB is mediated by the TATA-binding protein

The highly conserved protein kinase casein kinase II (CKII) is required for efficient Pol III transcription of the tRNA and 5S rRNA genes in Saccharomyces cerevisiae. Using purified factors from wild-type cells to complement transcription extracts from a conditional lethal mutant of CKII we show that TFIIIB is the CKII-responsive component of the Pol III transcription machinery. Dephosphorylation of TFIIIB eliminated its ability to complement CKII-depleted extract, and a single TFIIIB subunit, the TATA-binding protein (TBP), is a preferred substrate of CKII in vitro. Recombinant TBP purified from Escherichia coli is phosphorylated efficiently by CKII and, in the presence of a limiting amount of CKII, is able to substantially rescue transcription in CKII-deficient extract. Our results establish that TBP is a key component of the pathway linking CKII activity and Pol III transcription and suggest that TBP is the target of a CKII-mediated regulatory mechanism that can modulate Pol III transcription.

Domains of the Brf component of RNA polymerase III transcription factor IIIB (TFIIIB): functions in assembly of TFIIIB-DNA complexes and recruitment of RNA polymerase to the promoter

Saccharomyces cerevisiae transcription factor IIIB (TFIIIB) is composed of three subunits: the TATA-binding protein, the TFIIB-related protein Brf, and B". TFIIIB, which is brought to RNA polymerase III-transcribed genes indirectly through interaction with DNA-bound TFIIIC or directly through DNA recognition by the TATA-binding protein, in turn recruits RNA polymerase III to the promoter. N-terminally deleted derivatives of Brf have been examined for their ability to interact with DNA-bound TFIIIC and with the other components of TFIIIB and for participation in transcription. Brf(165-596), lacking 164 N-proximal TFIIB-homologous amino acids, is competent to participate in the assembly of TFIIIB-DNA complexes and in TFIIIC-independent transcription. Even deletion of the entire TFIIB-homologous half of the protein, as in Brf(317-596) and Brf(352-596), allows some interaction with DNA-bound TBP and with the B" component of TFIIIB to be retained. The function of Brf(165-596) in transcription has also been examined in the context of B" with small internal deletions. The ability of Brf with this sizable N-terminal segment deleted to function in TFIIIC-independent transcription requires segments of B" that are individually indispensable although required on an either/or basis, in the context of complete Brf. These findings suggest a functional complementarity and reciprocity between the Brf and B" components of TFIIIB.