Spatial organization of the core region of yeast TFIIIB-DNA complexes

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.

Extranucleosomal DNA enhances the activity of the LSD1/CoREST histone demethylase complex

The promoter regions of active genes in the eukaryotic genome typically contain nucleosomes post-translationally modified with a trimethyl mark on histone H3 lysine 4 (H3K4), while transcriptional enhancers are marked with monomethylated H3K4. The flavin-dependent monoamine oxidase LSD1 (lysine-specific demethylase 1, also known as KDM1) demethylates mono- and dimethylated H3K4 in peptide substrates, but requires the corepressor protein, CoREST, to demethylate nucleosome substrates. The molecular basis for how the LSD1/CoREST complex interacts with its physiological nucleosome substrate remains largely unknown. We examine here the role of extranucleosomal DNA beyond the nucleosome core particle for LSD1/CoREST function. Our studies of LSD1/CoREST's enzyme activity and nucleosome binding show that extranucleosomal DNA dramatically enhances the activity of LSD1/CoREST, and that LSD1/CoREST binds to the nucleosome as a 1:1 complex. Our photocrosslinking experiments further indicate both LSD1 and CoREST subunits are in close contact with DNA around the nucleosome dyad as well as extranucleosomal DNA. Our results suggest that the LSD1/CoREST interacts with extranucleosomal DNA when it productively engages its nucleosome substrate.

Disparity in the DNA translocase domains of SWI/SNF and ISW2

An ATP-dependent DNA translocase domain consisting of seven conserved motifs is a general feature of all ATP-dependent chromatin remodelers. While motifs on the ATPase domains of the yeast SWI/SNF and ISWI families of remodelers are highly conserved, the ATPase domains of these complexes appear not to be functionally interchangeable. We found one reason that may account for this is the ATPase domains interact differently with nucleosomes even though both associate with nucleosomal DNA 17–18 bp from the dyad axis. The cleft formed between the two lobes of the ISW2 ATPase domain is bound to nucleosomal DNA and Isw2 associates with the side of nucleosomal DNA away from the histone octamer. The ATPase domain of SWI/SNF binds to the same region of nucleosomal DNA, but is bound outside of the cleft region. The catalytic subunit of SWI/SNF also appears to intercalate between the DNA gyre and histone octamer. The altered interactions of SWI/SNF with DNA are specific to nucleosomes and do not occur with free DNA. These differences are likely mediated through interactions with the histone surface. The placement of SWI/SNF between the octamer and DNA could make it easier to disrupt histone–DNA interactions.

Bioorthogonal labeling of 5-hydroxymethylcytosine in genomic DNA and diazirine-based DNA photo-cross-linking probes

DNA is not merely a combination of four genetic codes, namely A, T, C, and G. It also contains minor modifications that play crucial roles throughout biology. For example, the fifth DNA base, 5-methylcytosine (5-mC), which accounts for ∼1% of all the nucleotides in mammalian genomic DNA, is a vital epigenetic mark. It impacts a broad range of biological functions, from development to cancer. Recently, an oxidized form of 5-methylcytosine, 5-hydroxymethylcytosine (5-hmC), was found to constitute the sixth base in the mammalian genome; it was believed to be another crucial epigenetic mark. Unfortunately, further study of this newly discovered DNA base modification has been hampered by inadequate detection and sequencing methods, because current techniques fail to differentiate 5-hmC from 5-mC. The immediate challenge, therefore, is to develop robust methods for ascertaining the positions of 5-hmC within the mammalian genome. In this Account, we describe our development of the first bioorthogonal, selective labeling of 5-hmC to specifically address this challenge. We utilize β-glucosyltransferase (βGT) to transfer an azide-modified glucose onto 5-hmC in genomic DNA. The azide moiety enables further bioorthogonal click chemistry to install a biotin group, which allows for detection, affinity enrichment, and, most importantly, deep sequencing of the 5-hmC-containing DNA. With this highly effective and selective method, we revealed the first genome-wide distribution of 5-hmC in the mouse genome and began to shed further light on the biology of 5-hmC. The strategy lays the foundation for developing high-throughput, single-base-resolution sequencing methods for 5-hmC in mammalian genomes in the future. DNA and RNA are not static inside cells. They interact with protein and other DNA and RNA in fundamental biological processes such as replication, transcription, translation, and DNA and RNA modification and repair. The ability to investigate these interactions will also be enhanced by developing and utilizing bioorthogonal probes. We have chosen the photoreactive diazirine photophore as a bioorthogonal moiety to develop nucleic acid probes. The small size and unique photo-cross-linking activity of diazirine enabled us to develop a series of novel cross-linking probes to streamline the study of protein-nucleic acid and nucleic acid-nucleic acid interactions. In the second half of this Account, we highlight a few examples of these probes.

Site-directed DNA crosslinking of large multisubunit protein-DNA complexes

Several methods have been developed to site-specifically incorporate photoreactive nucleotide analogs into DNA for the purpose of identifying the proteins and their domains that are in contact with particular regions of DNA. The synthesis of several deoxynucleotide analogs that have a photoreactive group tethered to the nucleotide base and the incorporation of these analogs into DNA are described. In a second approach, oligonucleotide with a photoreactive group attached to the phosphate backbone is chemically synthesized. The photoreactive oligonucleotide is then enzymatically incorporated into DNA by annealing it to a complementary DNA template and extending with DNA polymerase. Both approaches have been effectively used to map protein-DNA interactions in large multisubunit complexes such as the eukaryotic transcription or ATP-dependent chromatin remodeling complexes. Not only do these techniques map the binding sites of the various subunits in these complexes, but when coupled with peptide mapping also determine the protein domain that is in close proximity to the different DNA sites. The strength of these techniques is the ability to scan a large number of potential sites by making combinations of different DNA probes and is facilitated by using an immobilized DNA template for synthesis.

A diazirine-based nucleoside analogue for efficient DNA interstrand photocross-linking

A diazirine-based nucleoside analogue (DBN) efficiently forms DNA interstand cross-linking under near-UV irradiation. This new base analogue may find broad applications in biotechnology and phototherapy.

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

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

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.

Analyzing the handoff of DNA from UvrA to UvrB utilizing DNA-protein photoaffinity labeling

To better define the molecular architecture of nucleotide excision repair intermediates it is necessary to identify the specific domains of UvrA, UvrB, and UvrC that are in close proximity to DNA damage during the repair process. One key step of nucleotide excision repair that is poorly understood is the transfer of damaged DNA from UvrA to UvrB, prior to incision by UvrC. To study this transfer, we have utilized two types of arylazido-modified photoaffinity reagents that probe residues in the Uvr proteins that are closest to either the damaged or non-damaged strands. The damaged strand probes consisted of dNTP analogs linked to a terminal arylazido moiety. These analogs were incorporated into double-stranded DNA using DNA polymerase beta and functioned as both the damage site and the cross-linking reagent. The non-damaged strand probe contained an arylazido moiety coupled to a phosphorothioate-modified backbone of an oligonucleotide opposite the damaged strand, which contained an internal fluorescein adduct. Six site-directed mutants of Bacillus caldotenax UvrB located in different domains within the protein (Y96A, E99A, R123A, R183E, F249A, and D510A), and two domain deletions (Delta2 and Deltabeta-hairpin), were assayed. Data gleaned from these mutants suggest that the handoff of damaged DNA from UvrA to UvrB proceeds in a three-step process: 1) UvrA and UvrB bind to the damaged site, with UvrA in direct contact; 2) a transfer reaction with UvrB contacting mostly the non-damaged DNA strand; 3) lesion engagement by the damage recognition pocket of UvrB with concomitant release of UvrA.

Inhibition of TATA binding protein dimerization by RNA polymerase III transcription initiation factor Brf1

The Brf1 subunit of TFIIIB plays an important role in recruiting the TATA-binding protein (TBP) to the up-stream region of genes transcribed by RNA polymerase III. When TBP is not bound to promoters, it sequesters its DNA binding domain through dimerization. Promoter assembly factors therefore might be required to dissociate TBP into productively binding monomers. Here we show that Saccharomyces cerevisiae Brf1 induces TBP dimers to dissociate. The high affinity TBP binding domain of Brf1 is not sufficient to promote TBP dimer dissociation but in addition requires the TFIIB homology domain of Brf1. A model is proposed to explain how two distinct functional domains of Brf1 work in concert to dissociate TBP into monomers.

Role of the inhibitory DNA-binding surface of human TATA-binding protein in recruitment of human TFIIB family members

TATA box recognition by TATA-binding protein (TBP) is a key step in transcriptional initiation complex assembly on TATA-box-containing RNA polymerase (Pol) II and III promoters. This process is inhibited by the inhibitory DNA-binding (IDB) surface on the human TBP core domain (TBP(CORE)) and is stimulated by promoter-specific basal transcription factors, such as two human TFIIB family members, the Pol II factor TFIIB and the Pol III factor Brf2, which is required for transcription from TATA-box-containing Pol III promoters. In contrast, the third TFIIB family member, Brf1, which is required for transcription from TATA-less Pol III promoters, does not stimulate TBP binding to the TATA box. We show here that in addition to its role in regulating TBP binding to a TATA box, the TBP IDB surface is unexpectedly involved in TBP association with all three TFIIB family members. Interestingly, the loss of IDB function has specific and diverse effects on each TFIIB family member. Indeed, the IDB and prototypical TFIIB contact surfaces of TBP, which lie on opposite sides of the TBP(CORE), cooperate to form the wild-type TFIIB-TBP-TATA box complex. These results reveal how, through differential usage of opposite surfaces of the TBP(CORE), TBP can achieve versatility in the assembly of Pol II and Pol III promoter complexes with TFIIB family proteins.

A composite upstream sequence motif potentiates tRNA gene transcription in yeast

Transcription of eukaryotic tRNA genes relies on the TFIIIC-dependent recruitment of TFIIIB on a approximately 50 bp region upstream of the transcription start site (TSS). TFIIIC specifically interacts with highly conserved, intragenic promoter elements, while the contacts between TFIIIB and the upstream DNA have long been considered as largely non-specific. Through a computer search procedure designed to detect shared, yet degenerate sequence features, we have identified a conserved sequence pattern upstream of Saccharomyces cerevisiae tDNAs. This pattern consists of four regions in which particular sequences are over-represented. The most downstream of these regions surrounds the TSS, while the other three districts of sequence conservation (appearing as a centrally located TATA-like sequence flanked by T-rich elements on both sides) are located across the DNA region known to interact with TFIIIB. Upstream regions whose sequence conforms to this pattern were found to potentiate tRNA gene transcription, both in vitro and in vivo, by enhancing TFIIIB binding. A conserved pattern of DNA bendability was also revealed, with peaks of bending propensity centered on the TATA-like and the TSS regions. Sequence analysis of other eukaryotic genomes further revealed the widespread occurrence of conserved sequence patterns upstream of tDNAs, with striking lineage-specific differences in the number and sequence of conserved motifs. Our data strongly support the notion that tRNA gene transcription in eukaryotes is modulated by composite TFIIIB binding sites that may confer responsiveness to variation in TFIIIB activity and/or concentration.

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 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.

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".

A novel upstream RNA polymerase III promoter element becomes essential when the chromatin structure of the yeast U6 RNA gene is altered

The Saccharomyces cerevisiae U6 RNA gene, SNR6, possesses upstream sequences that allow productive binding in vitro of the RNA polymerase III (Pol III) transcription initiation factor IIIB (TFIIIB) in the absence of TFIIIC or other assembly factors. TFIIIC-independent transcription of SNR6 in vitro is highly sensitive to point mutations in a consensus TATA box at position -30. In contrast, the TATA box is dispensable for SNR6 transcription in vivo, apparently because TFIIIC bound to the intragenic A block and downstream B block can recruit TFIIIB via protein-protein interactions. A mutant allele of SNR6 with decreased spacing between the A and B blocks, snr6-Delta42, exhibits increased dependence on the upstream sequences in vivo. Unexpectedly, we find that in vivo expression of snr6-Delta42 is much more sensitive to mutations in a (dT-dA)(7) tract between the TATA box and transcription start site than to mutations in the TATA box itself. Inversion of single base pairs in the center of the dT-dA tract nearly abolishes transcription of snr6-Delta42, yet inversion of all 7 base pairs has little effect on expression, indicating that the dA-dT tract is relatively orientation independent. Although it is within the TFIIIB footprint, point mutations in the dT-dA tract do not inhibit TFIIIB binding or TFIIIC-independent transcription of SNR6 in vitro. In the absence of the chromatin architectural protein Nhp6, dT-dA tract mutations are lethal even when A-to-B block spacing is wild type. We conclude that the (dT-dA)(7) tract and Nhp6 cooperate to direct productive transcription complex assembly on SNR6 in vivo.

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.

Two novel dATP analogs for DNA photoaffinity labeling

Two new photoreactive dATP analogs, N(6)-[4-azidobenzoyl-(2-aminoethyl)]-2'-deoxyadenosine-5'-triphospha+ ++ te (AB-dATP) and N(6)-[4-[3-(trifluoromethyl)-diazirin-3-yl]benzoyl-(2-aminoethyl) ]-2 '-deoxyadenosine-5'-triphosphate (DB-dATP), were synthesized from 2'-deoxyadenosine-5'-monophosphate in a six step procedure. Synthesis starts with aminoethylation of dAMP and continues with rearrangement of N(1)-(2-aminoethyl)-2'-deoxyadenosine-5'-monophosphate to N(6)-(2-aminoethyl)-2'-deoxyadenosine-5'-monophosphate (N(6)-dAMP). Next, N(6)-dAMP is converted into the triphosphate form by first protecting the N-6 primary amino group before coupling the pyrophosphate. After pyrophosphorylation, the material is deprotected to yield N(6)-(2-aminoethyl)-2'-deoxyadenosine-5'-triphosphate (N(6)-dATP). The N-6 amino group is subsequently used to attach either a phenylazide or phenyldiazirine and the photoreactive nucleotide is then enzymatically incorporated into DNA. N(6)-dATP and its photoreactive analogs AB-dATP and DB-dATP were successfully incorporated into DNA using the exonuclease-free Klenow fragment of DNA polymerase I in a primer extension reaction. UV irradiation of the primer extension reaction with AB-dATP or DB-dATP showed specific photocrosslinking of DNA polymerase I to DNA.

Interactions between the tetratricopeptide repeat-containing transcription factor TFIIIC131 and its ligand, TFIIIB70. Evidence for a conformational change in the complex

In the transcription of tRNA and 5 S genes by RNA polymerase III, recruitment of the transcription factor (TF)IIIB is mediated by the promoter-bound assembly factor TFIIIC. A critical limiting step in this process is the interaction between the tetratricopeptide repeat (TPR)-containing subunit of TFIIIC (TFIIIC131) and the TFIIB-related factor Brf1p/TFIIIB70. To facilitate biochemical studies of this interaction, we expressed a fragment of TFIIIC131, TFIIIC131-(1-580), that includes the minimal TFIIIB70 interaction domain defined by two-hybrid studies together with adjacent sequences, up to the end of TPR9, implicated in the assembly reaction. TFIIIC131-(1-580) interacts with TFIIIB70 in solution and inhibits the formation of TFIIIB70.TFIIIC.DNA complexes. In a coupled equilibrium binding assay, the formation of TFIIIC131-(1-580).TFIIIB70 complexes was adequately described by a single-site binding model and yielded an apparent equilibrium dissociation constant of 334 +/- 23 nm. CD spectroscopy and limited proteolysis experiments defined a well structured and largely protease-resistant core in TFIIIC131-(1-580) comprising part of the hydrophilic amino terminus, TPR1-5, the intervening non-TPR region, and TPR6-8. CD spectra showed that trifluoroethanol induced significant alpha-helical structure in TFIIIC131-(1-580). A more modest monovalent ion-dependent CD difference was observed in mixtures of TFIIIC131-(1-580) and TFIIIB70, suggesting that formation of the binary complex may proceed with the acquisition of alpha-helicity.

TFIIIC-independent in vitro transcription of yeast tRNA genes

The most peculiar transcriptional property of eukaryotic tRNA genes, as well as of other genes served by RNA polymerase III, is their complete dependence on the intragenic interaction platform provided by transcription factor IIIC (TFIIIC) for the productive assembly of the TBP-containing initiation factor TFIIIB. The sole exception, in yeast, is the U6 RNA gene, which is able to exploit a TATAAATA element, 30 bp upstream of the transcription start site, for the TFIIIC-independent assembly of TFIIIB. To find out whether this extragenic core promoter organization and autonomous TFIIIB assembly capacity are unique features of the U6 gene or also apply to other genes transcribed by RNA polymerase III, we scanned the 5'-flanking regions (up to position -100) of the entire tRNA gene set of Saccharomyces cerevisiae searching for U6-like TATA motifs. Four tRNA genes harboring such a sequence motif around position -30 were identified and found to be transcribed in vitro by a minimal system only composed of TFIIIB and RNA polymerase III. In this system, start site selection is not at all affected by the absence of TFIIIC, which, when added, significantly stimulates transcription by determining an increase in the number, rather than in the efficiency of utilization, of productive initiation complexes. A specific TBP-TATA element interaction is absolutely required for TFIIIC-independent transcription, but the nearby sequence context also contributes to the efficiency of autonomous TFIIIB assembly. The existence of a TFIIIB assembly pathway leading to the faithful transcription of natural eukaryotic tRNA genes in the absence of TFIIIC provides novel insights into the functional flexibility of the eukaryotic tRNA gene transcription machinery and on its evolution from an ancestral RNA polymerase III system relying on upstream, TATA- centered control elements.

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.

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.