Yeast TATA-binding protein TFIID binds to TATA elements with both consensus and nonconsensus DNA sequences

Multimerization of the mouse TATA-binding protein (TBP) driven by its C-terminal conserved domain

The conformational states of the mouse TATA-binding protein (TBP) in solution were studied. A histidine tag and a factor Xa recognition site-carrying mouse TBP was expressed in E. coli, highly purified, and its fundamental functions as a TBP were demonstrated. We analyzed the molecular states of mouse TBP by gel filtration and glycerol gradient sedimentation, and found that TBP forms heterogeneous multimers in solution. Direct binding of TBP molecules to each other was proven by the far-Western procedure. Analyses using TBPs truncated at the N- and C-termini demonstrated that the functionally important C-terminal domain was responsible for homomultimer formation, and the N-terminal domain enhances multimerization. Furthermore, it was found that the TATA sequence dissociates homomultimers, and only monomeric TBP binds to the TATA-box. We suggest that TBP shares structural motifs in the C-terminal conserved domain for intermolecular interaction and TATA-binding.

TFIID sequence recognition of the initiator and sequences farther downstream in Drosophila class II genes

Immunopurified TFIID produces a large DNase I footprint over the hsp70, hsp26, and histone H3 promoters of Drosophila. These footprints span from the TATA element to a position approximately 35 nucleotides downstream from the transcription start site. Using a "missing nucleoside" analysis, four regions within the three promoters have been found to be important for TFIID binding: the TATA element, the initiator, and two regions located approximately 18 and 28 nucleotides downstream of the transcription start site. On the basis of the missing nucleoside data, the initiator appears to contribute as much to the affinity as the TATA element. However, there is weak conservation of the sequence in this region. To determine whether a preferred binding sequence exists in the vicinity of the initiator, the nucleotide composition of this region within the hsp70 promoter was randomized and then subjected to selection by TFIID. After five rounds of selection, the preferred sequence motif--G/A/T C/TAT/GTG--emerged. This motif is a close match to consensus sequences that have been derived by comparing the initiator region of numerous insect promoters. Selection of this sequence demonstrates that sequence-specific interactions downstream of the TATA element contribute to the interaction of TFIID on a wide spectrum of promoters.

Identical components of yeast transcription factor IIIB are required and sufficient for transcription of TATA box-containing and TATA-less genes

Specific transcription by RNA polymerase III requires recognition of the promoter-bound transcription factor IIIB (TFIIIB), of which the TATA-binding protein (TBP) is a subunit. The recruitment of TFIIIB to TATA-less genes is mediated by protein-protein interactions with transcription factor IIIC (TFIIIC) bound to the box A and box B elements. Here we examine interactions involved in the recruitment of TFIIIB to the TATA element-containing yeast U6 small nuclear RNA gene SNR6. TFIIIC is not required for the formation of TFIIIB-SNR6 gene complexes with purified components. The same three components of TFIIIB that are necessary for TFIIIC-dependent transcription of tRNA genes (recombinant TBP and Brf and the denaturing-gel-purified 90-kDa subunit) are required and sufficient for TATA box-directed U6 transcription. Despite its TFIIIC-independent, DNA sequence-dependent assembly, the TFIIIB-SNR6 complex shares important features with tDNA- and 5S rDNA-TFIIIB complexes, such as extent and location of footprint, stability, and resistance to heparin. These properties are clearly distinct from those of a TBP-SNR6 complex. In the SNR6 gene, box B, the primary binding site for TFIIIC, is suboptimally spaced relative to box A. At limiting TBP concentrations and on bare DNA, TFIIIC stimulates the formation of TFIIIB complexes with SNR6 but contributes poorly, at best, to the formation of properly placed complexes.

Protein/DNA crosslinking of a TFIID complex reveals novel interactions downstream of the transcription start

A protein--DNA complex containing TFIID has been analyzed by crosslinking. The TBP subunit of TFIID crosslinked to the TATA element but not to any of the regions further downstream which were tested. A 150 kd polypeptide, which corresponds in size to one of the TBP-associated factors (TAFs), crosslinked to a region between +10 and +15 and a second region between +35 and +47. Another polypeptide of greater than 205 kd (also a potential TAF) crosslinked preferentially to the region between +35 and +42. The +10 to +15 region has been recently implicated in hsp70 promoter recognition by TFIID, and the most downstream contacts overlap with the region where RNA polymerase II pauses on the hsp70 promoter in noninduced cells. Crosslinking revealed that as the salt concentration was increased, the TBP interaction was largely unaffected whereas the protein/DNA interactions downstream of the TATA element were disrupted. We propose that during the formation of a transcription complex, TATA-dependent interactions could be disrupted in the vicinity of the start site and the region immediately downstream. A protein contact downstream of +35 might function in pausing polymerase.

Sp1 is essential for both enhancer-mediated and basal activation of the TATA-less human adenosine deaminase promoter

Tissue-specific expression of the human adenosine deaminase (ADA) gene is mediated by transcriptional activation over a thousand-fold range. Cis-regulatory regions responsible for high and basal levels of activation include an enhancer and the proximal promoter region. While analyses of the T-cell specific enhancer have been carried out, detailed studies of the the promoter region or promoter-enhancer interactions have not. Examination of the promoter region by homology searches revealed six putative Sp1 binding sites. DNase I footprinting showed that Sp1 is able to bind these sites. Deletion analysis indicated that the proximal Sp1 site is required for activation of a reporter gene to detectable levels and that the more distal Sp1 sites further activate the level of expression. Inclusion of an ADA enhancer-containing fragment in these deletion constructions demonstrated that Sp1 sites are also essential for enhancer function. Apparently Sp1 controls not only low level expression but is also an integral part of the mechanism by which the enhancer achieves high level ADA expression. Mutagenesis of a potential TBP binding site at base pairs -21 to -26 decreased activity only two-fold indicating that it is not essential for transcriptional activation or enhancement.

Intragenic activating and repressing elements control transcription from the adenovirus IVa2 initiator

The downstream stimulatory segment of the adenovirus type 2 IVa promoter includes a TA-rich sequence that binds recombinant TATA-binding proteins (TBP) in vitro. We now demonstrate that when placed upstream of the IVa2, initiator, this TA-rich sequence operated as a TATA element but exhibited significantly lower transcriptional and TBP-binding activities than did the TATA box of the adenovirus major late (ML) promoter. In sharp contrast, changing the IVa2 TA-rich sequence in its natural, intragenic context to the ML TATA sequence increased the activity of the IVa2 promoter only slightly. In view of this discrepancy, we examined the effects of single, double, and clustered point mutations in the downstream sequence on the activity of a minimal IVa2 promoter. Mutations between positions +21 and +29 inhibited IVa2 transcription, in some cases to the very low level directed by the IVa2 initiator alone. By contrast, substitutions within the TA-rich sequence increased the efficiency of IVa2 transcription. These results indicated that the downstream, TA-rich sequence does not function as an intragenic TFIID-binding site but rather is included within a negative regulatory element. Electrophoretic mobility shift and methylation interference assays using wild-type and mutated, intragenic promoter sequences identified a HeLa cell component whose binding to the sequence +11 to +27 correlated with repression of IVa2 transcription, suggesting that a negative regulatory element is superimposed upon the intragenic sequence required for efficient transcription from the IVa2 initiator.

DNA sequence requirements for transcriptional initiator activity in mammalian cells

A transcriptional initiator (Inr) for mammalian RNA polymerase II can be defined as a DNA sequence element that overlaps a transcription start site and is sufficient for (i) determining the start site location in a promoter that lacks a TATA box and (ii) enhancing the strength of a promoter that contains a TATA box. We have prepared synthetic promoters containing random nucleotides downstream of Sp1 binding sites to determine the range of DNA sequences that convey Inr activity. Numerous sequences behaved as functional Inrs in an in vitro transcription assay, but the Inr activities varied dramatically. An examination of the functional elements revealed loose but consistent sequence requirements, with the approximate consensus sequence Py Py A+1 N T/A Py Py. Most importantly, almost every functional Inr that has been described fits into the consensus sequence that we have defined. Although several proteins have been reported to bind to specific Inrs, manipulation of those elements failed to correlate protein binding with Inr activity. The simplest model to explain these results is that all or most Inrs are recognized by a universal binding protein, similar to the functional recognition of all TATA sequences by the same TATA-binding protein. The previously reported proteins that bind near specific Inr elements may augment the strength of an Inr or may impart transcriptional regulation through an Inr.

Intragenic activating and repressing elements control transcription from the adenovirus IVa2 initiator

The downstream stimulatory segment of the adenovirus type 2 IVa promoter includes a TA-rich sequence that binds recombinant TATA-binding proteins (TBP) in vitro. We now demonstrate that when placed upstream of the IVa2, initiator, this TA-rich sequence operated as a TATA element but exhibited significantly lower transcriptional and TBP-binding activities than did the TATA box of the adenovirus major late (ML) promoter. In sharp contrast, changing the IVa2 TA-rich sequence in its natural, intragenic context to the ML TATA sequence increased the activity of the IVa2 promoter only slightly. In view of this discrepancy, we examined the effects of single, double, and clustered point mutations in the downstream sequence on the activity of a minimal IVa2 promoter. Mutations between positions +21 and +29 inhibited IVa2 transcription, in some cases to the very low level directed by the IVa2 initiator alone. By contrast, substitutions within the TA-rich sequence increased the efficiency of IVa2 transcription. These results indicated that the downstream, TA-rich sequence does not function as an intragenic TFIID-binding site but rather is included within a negative regulatory element. Electrophoretic mobility shift and methylation interference assays using wild-type and mutated, intragenic promoter sequences identified a HeLa cell component whose binding to the sequence +11 to +27 correlated with repression of IVa2 transcription, suggesting that a negative regulatory element is superimposed upon the intragenic sequence required for efficient transcription from the IVa2 initiator.

DNA sequence requirements for transcriptional initiator activity in mammalian cells

A transcriptional initiator (Inr) for mammalian RNA polymerase II can be defined as a DNA sequence element that overlaps a transcription start site and is sufficient for (i) determining the start site location in a promoter that lacks a TATA box and (ii) enhancing the strength of a promoter that contains a TATA box. We have prepared synthetic promoters containing random nucleotides downstream of Sp1 binding sites to determine the range of DNA sequences that convey Inr activity. Numerous sequences behaved as functional Inrs in an in vitro transcription assay, but the Inr activities varied dramatically. An examination of the functional elements revealed loose but consistent sequence requirements, with the approximate consensus sequence Py Py A+1 N T/A Py Py. Most importantly, almost every functional Inr that has been described fits into the consensus sequence that we have defined. Although several proteins have been reported to bind to specific Inrs, manipulation of those elements failed to correlate protein binding with Inr activity. The simplest model to explain these results is that all or most Inrs are recognized by a universal binding protein, similar to the functional recognition of all TATA sequences by the same TATA-binding protein. The previously reported proteins that bind near specific Inr elements may augment the strength of an Inr or may impart transcriptional regulation through an Inr.

The major histocompatibility complex (MHC) Ea promoter: sequences and factors at the initiation site

We have analysed the function of sequences in the TATA/initiator region of the promoter of Ea, a class II gene of the Major Histocompatibility Complex. We find that the Ea promoter contains an initiator element with a strong influence on transcription. We also find that the Ea promoter does contain a bona fide TATA box, which can be recognized by the TATA binding protein (TBP), and that TBP is required for transcriptional activity. For activity, TBP must be included within a larger TFIID complex, as Ea transcription in a heat-treated extract can be restored by immunopurified TFIID but not by TBP alone. On the other hand, the TATA motif can be eliminated without significantly affecting either the efficiency or the startsites of transcription. This suggests that TBP, even in this TATA-containing promoter, is held in place by other components of the initiation complex, regardless of its affinity for the underlying DNA.

Co-crystal structure of TBP recognizing the minor groove of a TATA element

The three-dimensional structure of a TATA-box binding polypeptide complexed with the TATA element of the adenovirus major late promoter has been determined by X-ray crystallography at 2.25 A resolution. Binding of the saddle-shaped protein induces a conformational change in the DNA, inducing sharp kinks at either end of the sequence TATAAAAG. Between the kinks, the right-handed double helix is smoothly curved and partially unwound, presenting a widened minor groove to TBP's concave, antiparallel beta-sheet. Side-chain/base interactions are restricted to the minor groove, and include hydrogen bonds, van der Waals contacts and phenylalanine-base stacking interactions.

Crystal structure of a yeast TBP/TATA-box complex

The 2.5 A crystal structure of a TATA-box complex with yeast TBP shows that the eight base pairs of the TATA box bind to the concave surface of TBP by bending towards the major groove with unprecedented severity. This produces a wide open, underwound, shallow minor groove which forms a primarily hydrophobic interface with the entire under-surface of the TBP saddle. The severe bend and a positive writhe radically alter the trajectory of the flanking B-form DNA.

Saccharomyces cerevisiae HSP70 heat shock elements are functionally distinct

The Saccharomyces cerevisiae HSP70 gene SSA1 has multiple heat shock elements (HSEs). To determine the significance of each of these sequences for expression of SSA1, we analyzed expression from a set of promoters containing point mutations in each of the HSEs, individually and in pairwise combinations. Of the three HSE-like sequences, two (HSE2 and HSE3) were active promoter elements; only one, HSE2, was active under basal growth conditions. Either HSE2 or HSE3 alone was able to drive SSA1 transcription at near-normal rates after heat shock. Both HSE2 and HSE3 were capable of driving basal transcription when placed in the context of the CYC1 promoter. Previous analysis had identified an upstream repressing sequence overlapping HSE2 that repressed basal transcription driven by HSE2. Our analysis showed that basal transcription driven by HSE3 was repressed both by the distant upstream repressing sequence and by closer flanking sequences. The ability to drive basal transcription is not inherent in all natural HSEs, since the HSEs from the heat-inducible SSA3 and SSA4 genes showed no basal activity when placed in the CYC1 vector. Gel mobility shift experiments showed that the same population of heat shock transcription factor molecules bound to HSEs capable of driving basal activity and to HSEs having very low or undetectable basal activity.

An upstream promoter element of the Acanthamoeba castellanii TBP gene binds a DNA sequence specific transcription activating protein, TPBF

We have characterized a positive-acting element in the upstream portion of the Acanthamoeba TBP gene promoter. The 27 bp element (TPE), located within the promoter between -97 and -70, stimulates transcription in an orientation independent fashion and tolerates modest changes in its distance from the TATA box. The TPE does not, however, function synergistically nor when positioned 3000 bp 5' or 260 base pairs 3' of the transcription start site. The TPE binds a DNA sequence-dependent factor, TPBF, which we have partly purified. TPBF was characterized using in vitro transcription, DNase I footprinting, methylation interference and electrophoretic mobility shift assays. TPBF does not have a counterpart in HeLa cells, but nonetheless strongly stimulates transcription of the Acanthamoeba TBP gene in mammalian extracts. Our results also suggest that there are additional positively and negatively acting elements within the TBP gene promoter, for which a model is presented.

Crystal structure of yeast TATA-binding protein and model for interaction with DNA

The C-terminal 179-aa region of yeast (Saccharomyces cerevisiae) TATA-binding protein (TBP), phylogenetically conserved and sufficient for many functions, formed crystals diffracting to 1.7-A resolution. The structure of the protein, determined by molecular replacement with coordinates from Arabidopsis TBP and refined to 2.6 A, differed from that in Arabidopsis slightly by an angle of about 12 degrees between two structurally nearly identical subdomains, indicative of a degree of conformational flexibility. A model for TBP-DNA interaction is proposed with the following important features: the long dimension of the protein follows the trajectory of the minor groove; two rows of basic residues conserved between the subdomains lie along the edges of the protein in proximity to the DNA phosphates; a band of hydrophobic residues runs down the middle of the groove; and amino acid residues whose mutation alters specificity for the second base of the TATA sequence are juxtaposed to that base.

A possible role for the yeast TATA-element-binding protein in DNA replication

The TATA-element-binding protein (TBP) is involved in the initiation of transcription by all three eukaryotic RNA polymerases. The following observations implicate TBP in the initiation of DNA replication at yeast chromosomal origins as well: (i) Recombinant yeast TBP binds specifically to functionally important regions of many yeast replication origins in vitro. (ii) TBP-binding sites from RNA polymerase II promoters can activate defective replication origins in vivo. (iii) Point mutations in TBP-binding sites that diminish their affinity for TBP in vitro reduce their ability to support replication in vivo.

Saccharomyces cerevisiae HSP70 heat shock elements are functionally distinct

The Saccharomyces cerevisiae HSP70 gene SSA1 has multiple heat shock elements (HSEs). To determine the significance of each of these sequences for expression of SSA1, we analyzed expression from a set of promoters containing point mutations in each of the HSEs, individually and in pairwise combinations. Of the three HSE-like sequences, two (HSE2 and HSE3) were active promoter elements; only one, HSE2, was active under basal growth conditions. Either HSE2 or HSE3 alone was able to drive SSA1 transcription at near-normal rates after heat shock. Both HSE2 and HSE3 were capable of driving basal transcription when placed in the context of the CYC1 promoter. Previous analysis had identified an upstream repressing sequence overlapping HSE2 that repressed basal transcription driven by HSE2. Our analysis showed that basal transcription driven by HSE3 was repressed both by the distant upstream repressing sequence and by closer flanking sequences. The ability to drive basal transcription is not inherent in all natural HSEs, since the HSEs from the heat-inducible SSA3 and SSA4 genes showed no basal activity when placed in the CYC1 vector. Gel mobility shift experiments showed that the same population of heat shock transcription factor molecules bound to HSEs capable of driving basal activity and to HSEs having very low or undetectable basal activity.

Promoter elements determining weak expression of the GAL4 regulatory gene of Saccharomyces cerevisiae

The GAL4 gene of Saccharomyces cerevisiae (encoding the activator of transcription of the GAL genes) is poorly expressed and is repressed during growth on glucose. To determine the basis for its weak expression and to identify DNA sequences recognized by proteins that activate transcription of a gene that itself encodes an activator of transcription, we have analyzed GAL4 promoter structure. We show that the GAL4 promoter is about 90-fold weaker than the strong GAL1 promoter and at least 7-fold weaker than the feeble URA3 promoter and that this low level of GAL4 expression is primarily due to a weak promoter. By deletion mapping, the GAL4 promoter can be divided into three functional regions. Two of these regions contain positive elements; a distal region termed the UASGAL4 (upstream activation sequence) contains redundant elements that increase promoter function, and a central region termed the UESGAL4 (upstream essential sequence) is essential for even basal levels of GAL4 expression. The third element, an upstream repression sequence, mediates glucose repression of GAL4 expression and is located between the UES and the transcriptional start site. The UASGAL4 is unusual because it is not interchangable with UAS elements in other yeast promoters; it does not function as a UAS element when inserted in a CYC1 promoter, and a normally strong UAS functions poorly in place of UASGAL4 in the GAL4 promoter. Similarly, the UES element of GAL4 does not function as a TATA element in a test promoter, and consensus TATA elements do not function in place of UES elements in the GAL4 promoter. These results suggest that GAL4 contains a weak TATA-less promoter and that the proteins regulating expression of this regulatory gene may be novel and context specific.

Promoter elements determining weak expression of the GAL4 regulatory gene of Saccharomyces cerevisiae

The GAL4 gene of Saccharomyces cerevisiae (encoding the activator of transcription of the GAL genes) is poorly expressed and is repressed during growth on glucose. To determine the basis for its weak expression and to identify DNA sequences recognized by proteins that activate transcription of a gene that itself encodes an activator of transcription, we have analyzed GAL4 promoter structure. We show that the GAL4 promoter is about 90-fold weaker than the strong GAL1 promoter and at least 7-fold weaker than the feeble URA3 promoter and that this low level of GAL4 expression is primarily due to a weak promoter. By deletion mapping, the GAL4 promoter can be divided into three functional regions. Two of these regions contain positive elements; a distal region termed the UASGAL4 (upstream activation sequence) contains redundant elements that increase promoter function, and a central region termed the UESGAL4 (upstream essential sequence) is essential for even basal levels of GAL4 expression. The third element, an upstream repression sequence, mediates glucose repression of GAL4 expression and is located between the UES and the transcriptional start site. The UASGAL4 is unusual because it is not interchangable with UAS elements in other yeast promoters; it does not function as a UAS element when inserted in a CYC1 promoter, and a normally strong UAS functions poorly in place of UASGAL4 in the GAL4 promoter. Similarly, the UES element of GAL4 does not function as a TATA element in a test promoter, and consensus TATA elements do not function in place of UES elements in the GAL4 promoter. These results suggest that GAL4 contains a weak TATA-less promoter and that the proteins regulating expression of this regulatory gene may be novel and context specific.

Mechanism of initiator-mediated transcription: evidence for a functional interaction between the TATA-binding protein and DNA in the absence of a specific recognition sequence

Promoters containing Sp1 binding sites and an initiator element but lacking a TATA box direct high levels of accurate transcription initiation by using a mechanism that requires the TATA-binding protein (TBP). We have begun to address the role of TBP during transcription from Sp1-initiator promoters by varying the nucleotide sequence between -14 and -33 relative to the start site. With each of several promoters containing different upstream sequences, we detected accurate transcription both in vitro and in vivo, but the promoter strengths varied widely, particularly with the in vitro assay. The variable promoter activities correlated with, but were not proportional to, the abilities of the upstream sequences to function as TATA boxes, as assessed by multiple criteria. These results confirm that accurate transcription can proceed in the presence of an initiator, regardless of the sequence present in the -30 region. However, the results reveal a role for this upstream region, most consistent with a model in which initiator-mediated transcription requires binding of TBP to the upstream DNA in the absence of a specific recognition sequence. Moreover, in vivo it appears that the promoter strength is modulated less severely by altering the -30 sequence, consistent with a previous suggestion that TBP is not rate limiting in vivo for TATA-less promoters. Taken together, these results suggest that variations in the structure of a core promoter might alter the rate-limiting step for transcription initiation and thereby alter the potential modes of transcriptional regulation, without severely changing the pathway used to assemble a functional preinitiation complex.

Mechanism of initiator-mediated transcription: evidence for a functional interaction between the TATA-binding protein and DNA in the absence of a specific recognition sequence

Promoters containing Sp1 binding sites and an initiator element but lacking a TATA box direct high levels of accurate transcription initiation by using a mechanism that requires the TATA-binding protein (TBP). We have begun to address the role of TBP during transcription from Sp1-initiator promoters by varying the nucleotide sequence between -14 and -33 relative to the start site. With each of several promoters containing different upstream sequences, we detected accurate transcription both in vitro and in vivo, but the promoter strengths varied widely, particularly with the in vitro assay. The variable promoter activities correlated with, but were not proportional to, the abilities of the upstream sequences to function as TATA boxes, as assessed by multiple criteria. These results confirm that accurate transcription can proceed in the presence of an initiator, regardless of the sequence present in the -30 region. However, the results reveal a role for this upstream region, most consistent with a model in which initiator-mediated transcription requires binding of TBP to the upstream DNA in the absence of a specific recognition sequence. Moreover, in vivo it appears that the promoter strength is modulated less severely by altering the -30 sequence, consistent with a previous suggestion that TBP is not rate limiting in vivo for TATA-less promoters. Taken together, these results suggest that variations in the structure of a core promoter might alter the rate-limiting step for transcription initiation and thereby alter the potential modes of transcriptional regulation, without severely changing the pathway used to assemble a functional preinitiation complex.

Activation of a dual adenovirus promoter containing nonconsensus TATA motifs in Schizosaccharomyces pombe: role of TATA sequences in the efficiency of transcription

The role of TATA elements in the expression of a mammalian promoter was investigated in the fission yeast Schizosaccharomyces pombe, by studying the human adenovirus E2-early promoter. This is a unique dual promoter with two nonconsensus TATA elements directing transcription from two cap sites, +1 and -26. A sequence TTAAGA provides the TATA box function for the +1 promoter, whereas a sequence TAAATT, with a closer resemblance to the consensus (TATAA/TA) provides this function for the -26 promoter. Yet, in human cells, the +1 promoter is transcribed about 20 fold more efficiently than the -26 promoter. We found that both promoters are transcribed faithfully in S. pombe with start sites identical or close to those found in human cells. Surprisingly, the relative ratio of expression for the +1 and -26 promoters was exactly reversed in S. pombe cells. This reversal appeared to be due to the relatively weak binding of S. pombe TATA binding protein to the TTAAGA motif, rather than to its rate of dissociation. Furthermore, we show that in S. pombe, promoter expression correlates well with the nucleotide sequence of the TATA element rather than the context in which it is placed. By contrast, it is the context of the TATA element, rather than its nucleotide sequence that appears to be critical for promoter expression in human cells. Our data suggest the existence of one or more additional factors in human cells that permit the utilization of nonconsensus TATA elements. S. pombe appears to lack these factors.

Sites of RNA polymerase III transcription initiation and Ty3 integration at the U6 gene are positioned by the TATA box

The function of a TATA element in RNA polymerase (EC 2.7.7.6) III transcription of a naturally TATA-containing U6 snRNA gene and a naturally TATA-less tRNA gene was probed by transcription and Ty3 transposition analyses. Deletion of the TATA box from a U6 minigene did not abolish transcription and Ty3 integration but changed the positions of initiation and insertion. Insertion of the U6 TATA box at three positions upstream of the TATA-less SUP2 tRNA(Tyr) gene resulted in novel transcription initiation and Ty3 integration patterns that depended upon position of the insertion. Nevertheless, the predominant tRNA gene initiation sites were not affected by insertion of the TATA sequence and remained at a fixed distance from the internal box A promoter element. Insertions of the TATA box upstream of a SUP2 box A mutant affected the level of transcription and restricted the use of upstream start sites, but they neither enhanced the use of TATA-dependent initiation sites nor restored expression to the level of the wild-type gene. We conclude that (i) the U6 TATA box is essential in vivo for correct initiation but not for transcription, (ii) a TATA box does not compensate for a weak box A sequence and so cannot perform equivalently, and (iii) the TATA-binding protein, and probably components of transcription factor IIIB, are present on the target at the time of Ty3 integration.

An ATP-dependent inhibitor of TBP binding to DNA

An activity in yeast nuclear extracts (termed ADI) is described that inhibits the binding of the TATA-binding protein (TBP) to DNA in an ATP-dependent manner. The effect is reversible, ATP specific, rapid, and is not promoter specific. ADI is specific for TBP because three other protein-DNA complexes are not affected by ADI. The action of ADI is blocked by association of TFIIA with the TBP-DNA complex. ADI activity at the adenovirus major late promoter requires a segment of DNA upstream from the TATA sequence, suggesting that ADI recognizes aspects of both TBP and DNA. The evolutionarily conserved carboxy-terminal domain of TBP is sufficient for ADI recognition, and amino acids in the basic region of TBP are required for ADI action. ADI can repress transcription in vitro in an ATP-dependent manner. In the presence of ADI, both TFIIA and TBP are required to commit a template to transcription. A model of ADI action is proposed, and possible roles of ADI in the regulation of the transcription complex assembly are discussed.

Effect of the non-conserved N-terminus on the DNA binding activity of the yeast TATA binding protein

We have studied the DNA binding activity of recombinant yeast TATA Binding Protein (TBP) with particular interest in the role played by the non-conserved N-terminal domain. By comparing the DNA binding activity of wild type yeast TBP with a mutant form of TBP that lacks the non-conserved N-terminal domain (TBP delta 57), we have determined that the N-terminus of TBP alters both the shape and the stability of the TBP-DNA complex. Measurements of the DNA bending angle indicate that the N-terminus enhances the bending of the DNA that is induced by TBP binding and greatly destabilizes the TBP-DNA complex during native gel electrophoresis. In solution, the N-terminus has only a slight effect on the equilibrium dissociation constant and the dissociation rate constant. However, the N-terminal domain reduces the association rate constant in a temperature dependent manner and increases the apparent activation energy of the TBP-DNA complex formation by 3 kcal/mole. These data suggest that a conformational change involving the N-terminus of TBP may be one of the isomerization steps in the formation of a stable TBP-DNA complex.

Crystal structure of TFIID TATA-box binding protein

The structure of a central component of the eukaryotic transcriptional apparatus, a TATA-box binding protein (TBP or TFIID tau) from Arabidopsis thaliana, has been determined by X-ray crystallography at 2.6 A resolution. This highly symmetric alpha/beta structure contains a new DNA-binding fold, resembling a molecular 'saddle' that sits astride the DNA. The DNA-binding surface is a curved, antiparallel beta-sheet. When bound to DNA, the convex surface of the saddle would be presented for interaction with other transcription initiation factors and regulatory proteins.

A yeast TFIIB-related factor involved in RNA polymerase III transcription

A suppressor gene was identified, which in high copy number rescues a temperature-sensitive mutation in yeast TATA-binding protein (TBP). Suppression was allele specific because the suppressor did not rescue the temperature-sensitive phenotype of another TBP mutant. This suppressor gene encodes a 596-amino-acid protein of which the amino-terminal half is homologous to the Pol II-specific factor TFIIB. Disruption of this gene, termed BRF1, showed it to be essential for growth of yeast. Deletion of sequences at either the amino or carboxyl terminus of BRF1 gave both temperature- and cold-sensitive phenotypes. These temperature- and cold-sensitive strains were used to prepare extracts deficient in BRF1 activity and were tested for transcriptional activity by RNA polymerases I, II, and III in vitro. BRF1-deficient extracts are defective in Pol III transcription and can be reconstituted for Pol III transcription by the addition of recombinant BRF1. Western analysis shows that BRF1 is present in TFIIIB but not the TFIIIC fraction, suggesting that it is a component of TFIIIB. We propose that BRF1 plays a role in Pol III initiation analogous to the role played by TFIIB for Pol II in its interaction with TBP and polymerase. The identification of a Pol III-specific TFIIB-like factor extends the previously noted similarity of transcriptional initiation by the three nuclear polymerases.

Uncoupling gene activity from chromatin structure: promoter mutations can inactivate transcription of the yeast HSP82 gene without eliminating nucleosome-free regions

DNase I-hypersensitive sites represent "nucleosome-free" regions in chromatin where the underlying DNA sequence is highly accessible to trans-acting proteins. Here we demonstrate that it is possible to uncouple gene activity from hypersensitive site formation. Point or substitution mutations were introduced into the promoter of the yeast chromosomal HSP82 gene, encoding the 83-kDa heat shock protein (HSP), via site-directed integration. Mutating either the TATA box or heat shock element 1 (HSE1) significantly reduced basal and heat-induced transcription while mutating both essentially inactivated expression. Dormant transcription units exhibited arrays of sequence-positioned nucleosomes; nevertheless, the inactivated genes still retained a hypersensitive site within their mutated promoters. In addition, all yeast strains maintained a heat-inducible hypersensitive site at -600 base pairs (bp), while several mutant strains converted a constitutive hypersensitive site at -300 bp into a heat-inducible one. Thus, mutations in cis-acting elements within a promoter can inactivate transcription without eliminating nucleosome-free regions.

Isolation of genomic DNA encoding transcription factor TFIID from Acanthamoeba castellanii: characterization of the promoter

We have isolated a genomic clone encoding Acanthamoeba castellanii TFIID. The clone contains the entire TFIID gene, 300 bp of 5' promoter sequences and several hundred base pairs of 3' non-coding sequence. The coding region is interrupted by two short introns, but is otherwise identical to Acanthamoeba TFIID cDNA. Comparisons between forty four Acanthamoeba intron 5' and 3' boundaries suggest a 5' splice site consensus of GTACG(T/C) and a 3' consensus of CAG. We determined the position of the transcription initiation site used in vivo, and show that the same site is used in vitro by homologous nuclear extracts. Deletion analysis of the promoter region shows that the minimal promoter required for efficient expression in vitro is located between -97 and +4 relative to the transcription start site. Three regions within the promoter are important for transcription in vitro; sequences between -97 and -35, the TATAAA box and the initiation region. The initiation region is dispensable but appears to position the transcription start site relative to the TATAAA box. The TATAAA box is absolutely required for transcription initiation whereas the upstream region stimulates transcription approximately five-fold.

Identification of regulatory elements within the minimal promoter region of the human endogenous ERV9 proviruses: accurate transcription initiation is controlled by an Inr-like element

ERV9 is a low repeated family of human endogenous retroviral elements whose expression is mainly detectable in undifferentiated embryonal carcinoma NT2/D1 cells. In this report we have analyzed the minimal promoter region located within the ERV9 LTR. Using the transient CAT expression assay we have identified the minimal promoter region, which includes sequences spanning from -70 to +6 relative to the major transcription start site. Deletion analysis, primer extension mapping of the transcription start sites and DNA-protein interactions assays have allowed us to define two important regions within the ERV9 minimal promoter. One region located between -70 to -39 acts as a transcriptional activating sequence and contains an Sp 1 binding site. The second region from -7 to +6, which resembles an initiator element (Inr), was necessary for the correct transcription start site utilization, and binds to a regulatory protein. Cross-competition experiments using various Inr elements have indicated that the protein that binds to the ERV9 Inr element can be competed by the HIV-1 and TdT Inr sequences.

Positive and negative elements regulate a melanocyte-specific promoter

Melanocytes are specialized cells residing in the hair follicles, the eye, and the basal layer of the human epidermis whose primary function is the production of the pigment melanin, giving rise to skin, hair, and eye color. Melanogenesis, a process unique to melanocytes that involves the processing of tyrosine by a number of melanocyte-specific enzymes, including tyrosinase and tyrosinase-related protein 1 (TRP-1), occurs only after differentiation from the melanocyte precursor, the melanoblast. In humans, melanogenesis is inducible by UV irradiation, with melanin being transferred from the melanocyte in the epidermis to the surrounding keratinocytes as protection from UV-induced damage. Excessive exposure to UV, however, is the primary cause of malignant melanoma, an increasingly common and highly aggressive disease. As an initial approach to understanding the regulation of melanocyte differentiation and melanocyte-specific transcription, we have isolated the gene encoding TRP-1 and examined the cis- and trans-acting factors required for cell-type-specific expression. We find that the TRP-1 promoter comprises both positive and negative regulatory elements which confer efficient expression in a TRP-1-expressing, pigmented melanoma cell line but not in NIH 3T3 or JEG3 cells and that a minimal promoter extending between -44 and +107 is sufficient for cell-type-specific expression. Assays for DNA-protein interactions coupled with extensive mutagenesis identified three factors, whose binding correlated with the function of two positive and one negative regulatory element. One of these factors, termed M-box-binding factor 1, binds to an 11-bp motif, the M box, which acts as a positive regulatory element both in TRP-1-expressing and -nonexpressing cell lines, despite being entirely conserved between the melanocyte-specific tyrosinase and TRP-1 promoters. The possible mechanisms underlying melanocyte-specific gene expression are discussed.

Positive and negative elements regulate a melanocyte-specific promoter

Melanocytes are specialized cells residing in the hair follicles, the eye, and the basal layer of the human epidermis whose primary function is the production of the pigment melanin, giving rise to skin, hair, and eye color. Melanogenesis, a process unique to melanocytes that involves the processing of tyrosine by a number of melanocyte-specific enzymes, including tyrosinase and tyrosinase-related protein 1 (TRP-1), occurs only after differentiation from the melanocyte precursor, the melanoblast. In humans, melanogenesis is inducible by UV irradiation, with melanin being transferred from the melanocyte in the epidermis to the surrounding keratinocytes as protection from UV-induced damage. Excessive exposure to UV, however, is the primary cause of malignant melanoma, an increasingly common and highly aggressive disease. As an initial approach to understanding the regulation of melanocyte differentiation and melanocyte-specific transcription, we have isolated the gene encoding TRP-1 and examined the cis- and trans-acting factors required for cell-type-specific expression. We find that the TRP-1 promoter comprises both positive and negative regulatory elements which confer efficient expression in a TRP-1-expressing, pigmented melanoma cell line but not in NIH 3T3 or JEG3 cells and that a minimal promoter extending between -44 and +107 is sufficient for cell-type-specific expression. Assays for DNA-protein interactions coupled with extensive mutagenesis identified three factors, whose binding correlated with the function of two positive and one negative regulatory element. One of these factors, termed M-box-binding factor 1, binds to an 11-bp motif, the M box, which acts as a positive regulatory element both in TRP-1-expressing and -nonexpressing cell lines, despite being entirely conserved between the melanocyte-specific tyrosinase and TRP-1 promoters. The possible mechanisms underlying melanocyte-specific gene expression are discussed.

A comparison of the DNA bending activities of the DNA binding proteins CRP and TFIID

Protein-induced DNA bending is of importance in the formation of complex nucleoprotein assemblies such as those involved in the initiation of DNA replication or transcription initiation. We have compared the DNA bending characteristics of the Escherichia coli cyclic AMP receptor protein (CRP or CAP), an archetypal DNA bending protein, to those of TFIID, the eukaryotic TATA-element binding transcription factor. By altering the helical phasing between a CRP binding site and the E. coli melR promoter we have mapped a DNA sequence-directed bend in the downstream region of the promoter. This intrinsic DNA bend may be important in the regulation of the melR promoter by CRP in vivo. Gel retardation assays and DNAse I footprinting show that human TFIID binds to the melR promoter - 10 region. Taking advantage of this fact, and using the CRP-induced DNA bend as a standard, we have employed phase sensitive detection to show that the DNA bend angle induced by TFIID is far less than that induced by CRP. Further evidence to support this conclusion comes from a comparison of the relative mobilities of CRP-DNA and TFIID-DNA complexes. These results place limits on the role of any DNA bending induced by TFIID alone in the initiation of transcription.

Regulatory sequences for expressing genes in oomycete fungi

Promoter and terminator sequences from a range of species were tested for activity in the oomycetes, a group of lower fungi that bear an uncertain taxonomic affinity to other organisms and in which little is known of the sequences required for transcription. Transient assays, using the reporter gene beta-glucuronidase (GUS), were used to examine the function of these promoters and terminators in the plant pathogens Phytophthora infestans and P. megasperma f. sp. glycinea, and in the saprophytic water mold, Achlya ambisexualis. Oomycete promoters, isolated from the ham34 and hsp70 genes of Bremia lactucae and the actin gene of P. megasperma f. sp. glycinea, resulted in high levels of GUS accumulation in each of the three oomycetes. In contrast, little or no activity was detected when promoters from higher fungi (four ascomycetes and one basidiomycete), plants, and animals were tested. The terminator from the ham34 gene resulted in much higher levels of GUS accumulation than did others, although an oomycete terminator was not absolutely required for expression. Transcript mapping of RNA from stable transformants confirmed accurate initiation from the B. lactucae hsp70 promoter and termination within 3' ham34 sequences in P. infestans. Our results indicate that the transcriptional machinery of the oomycetes differs significantly from that of the higher fungi, but that enough conservation exists within the class to allow vectors developed from one oomycete species to be used for others.

Functional binding of the "TATA" box binding component of transcription factor TFIID to the -30 region of TATA-less promoters

Many viral and cellular promoters transcribed in higher eukaryotes by RNA polymerase II lack obvious A+T-rich sequences, called "TATA" boxes, that bind the transcription factor TFIID. One such TATA-less promoter, the simian virus 40 major late promoter, contains a genetically important sequence element 30 base pairs upstream of its transcription initiation site that has no obvious sequence similarity to a TATA box. We show here that the cloned human TATA box-binding protein, hTFIID tau, functionally binds to this upstream sequence element, although with an affinity one-sixth of that to which it binds the TATA box of the adenovirus type 2 major late promoter. Analysis of point mutations in the -30 element of the simian virus 40 major late promoter shows that the affinity of binding correlates with the efficiency of transcription from this promoter. Furthermore, this element has genetic properties similar to those of a TATA box. (i) It directs RNA polymerase II to initiate transcription approximately 30 base pairs downstream of its location, and (ii) inactivation of this element results in increased heterogeneity in the sites of transcription initiation. All of five other TATA-less promoters tested were found to contain a sequence approximately 30 base pairs upstream of their major transcription initiation sites to which hTFIID tau binds. We conclude that many, if not all, TATA-less promoters differ from TATA box-containing promoters simply in the affinity of their -30 regions for binding of TFIID, with functional binding of TFIID supported in part by other nearby sequence elements of the promoter.

Anatomy of an unusual RNA polymerase II promoter containing a downstream TATA element

The adenovirus type 2 IVa2 promoter lacks a conventional TATA element yet directs transcription from two closely spaced initiation sites. To define elements required for in vitro transcription of this promoter, IVa2 templates carrying 5' deletions or linker-scanning mutations were transcribed in HeLa whole-cell extracts and the transcripts were analyzed by primer extension. Mutation of the sequence centered on position -47, which is specifically recognized by a cellular factor, reduced the efficiency of IVa2 transcription two- to threefold, whereas mutation of the sequence centered on position -30 selectively impaired utilization of the minor in vivo initiation site. Utilization of the major in vivo site was decreased no more than fivefold by deletion of all sequences upstream of position -15. By contrast, mutation of the region from +13 to +19 or of the initiation region severely impaired IVa2 transcription. The sequence spanning the initiation sites was sufficient to direct accurate initiation by RNA polymerase II from the major in vivo site. Thus, the two initiation sites of the IVa2 promoter are specified by independent elements, and a downstream element is the primary determinant of efficient transcription from both of these sites. The downstream element identified by mutational analysis altered the TATA element-like sequence TATAGAAA lying at positions +21 to +14 in the coding strand. Transcription from the wild-type IVa2 promoter was severely inhibited when endogenous TFIID was inactivated by mild heat treatment. Exogenous human TATA-binding protein (TBP) synthesized in Escherichia coli restored specific IVa2 transcription from both initiation sites when added to such heat-treated extracts. Although efficient IVa2 transcription requires both the downstream TATA sequence and active TFIID, bacterially synthesized TBP also stimulated the low level of IVa2 transcription observed when the TATA sequence was mutated to a sequence that failed to bind TBP.

Anatomy of an unusual RNA polymerase II promoter containing a downstream TATA element

The adenovirus type 2 IVa2 promoter lacks a conventional TATA element yet directs transcription from two closely spaced initiation sites. To define elements required for in vitro transcription of this promoter, IVa2 templates carrying 5' deletions or linker-scanning mutations were transcribed in HeLa whole-cell extracts and the transcripts were analyzed by primer extension. Mutation of the sequence centered on position -47, which is specifically recognized by a cellular factor, reduced the efficiency of IVa2 transcription two- to threefold, whereas mutation of the sequence centered on position -30 selectively impaired utilization of the minor in vivo initiation site. Utilization of the major in vivo site was decreased no more than fivefold by deletion of all sequences upstream of position -15. By contrast, mutation of the region from +13 to +19 or of the initiation region severely impaired IVa2 transcription. The sequence spanning the initiation sites was sufficient to direct accurate initiation by RNA polymerase II from the major in vivo site. Thus, the two initiation sites of the IVa2 promoter are specified by independent elements, and a downstream element is the primary determinant of efficient transcription from both of these sites. The downstream element identified by mutational analysis altered the TATA element-like sequence TATAGAAA lying at positions +21 to +14 in the coding strand. Transcription from the wild-type IVa2 promoter was severely inhibited when endogenous TFIID was inactivated by mild heat treatment. Exogenous human TATA-binding protein (TBP) synthesized in Escherichia coli restored specific IVa2 transcription from both initiation sites when added to such heat-treated extracts. Although efficient IVa2 transcription requires both the downstream TATA sequence and active TFIID, bacterially synthesized TBP also stimulated the low level of IVa2 transcription observed when the TATA sequence was mutated to a sequence that failed to bind TBP.

Regulation of delayed-early gene transcription by dual TATA boxes

The 39K Autographa californica nuclear polyhedrosis virus (AcMNPV) gene is highly expressed throughout the virus life cycle and is controlled by tandem promoters that exhibit features of early and late baculovirus promoters. Late transcripts initiate at a conserved TAAG motif, while early transcripts are heterogeneous and initiate near a conserved CAGT motif. To define the nucleotide sequences that regulate early transcription of the 39K gene, a series of mutations was generated by substitution of 10-bp stretches in the 39K promoter with a BglII linker. The effects of these mutations on transcription from the early promoter were determined by transient expression and primer extension assays in the presence of the viral trans-activator IE1 gene. Mutations in the region from -15 to -44 revealed that early 39K transcription was controlled by dual TATA boxes. These TATA boxes are separated by 10 bp, which partially accounts for the heterogeneity in early 39K transcripts. Transcripts initiating at the CAGT motif (proximal transcripts) were abolished by deletion of the proximal TATA box located at -29 relative to CAGT. Proximal transcripts were not affected by alterations in the distal TATA motif located at -39 relative to the CAGT. Similarly, transcripts initiating upstream of CAGT (distal transcripts) were eliminated by mutations in the distal TATA but were unaffected by substitutions in the proximal TATA box. Proximal transcripts were not detected with a plasmid containing mutations in the CAGT motif, although the distal transcripts were unaffected by CAGT mutations. When the sequences surrounding the initiation site for the distal transcripts were altered, the start site was shifted one nucleotide, but transcription was not quantitatively affected. These results suggest that early 39K transcription is controlled by two distinct TATA elements, one that is dependent on an initiator and one in which the site of initiation is determined by the TATA element alone. Mutations in an upstream region from -45 to -68 relative to the CAGT motif had a quantitative effect but did not alter the heterogeneous pattern of early transcripts, suggesting these sequences function as an upstream regulatory region. Analysis of late transcription indicated that the TAAG element was essential, while transcription was unaffected by other mutations.

Comparative analysis of the beta transducin family with identification of several new members including PWP1, a nonessential gene of Saccharomyces cerevisiae that is divergently transcribed from NMT1

While investigating the expression of the Saccharomyces cerevisiae myristoyl-CoA:protein N-myristoyltransferase gene (NMT: E.C. 2.3.1.97) by Northern blot analysis, we observed another RNA transcript whose expression resembled that of NMT1 during meiosis and was derived from a gene located less than 1 kb immediately upstream of NMT1. This new gene, designated PWP1 (for periodic tryptophan protein), is divergently transcribed from NMT1 and encodes a 576-residue protein. Null mutants of PWP1 are viable, but their growth is severely retarded and steady-state levels of several cellular proteins (including at least two proteins that label with exogenous [3H]myristic acid) are drastically reduced. New methods for database searching and assessing the statistical significance of sequence similarities identify PWP1 as a member of the beta-transducin protein superfamily. Two other previously unrecognized beta-transducin-like proteins (S. cerevisiae MAK11 and D. discoideum AAC3) were also identified, and an unexpectedly high degree of sequence homology was found between a Chlamydomonas beta-like polypeptide and the C12.3 gene of chickens. A systematic and quantitative comparative analysis resulted in classifying all beta-transducin-like sequences into 11 nonorthologous families. Based on specific sequence attributes, however, not all beta-transducin-like sequences are expected to be functionally similar, and quantitative criteria for inferring functional analogies are discussed. Possible roles of repetitive tryptophan residues in proteins are also considered.

A bipartite DNA binding domain composed of direct repeats in the TATA box binding factor TFIID

Point mutations in residues comprising the interrupted direct repeats of TFIID eliminated DNA binding in an electrophoretic mobility shift assay. In contrast, mutations in nonconserved residues within the direct repeat regions or in lysine residues comprising the intervening basic repeat had no effect on DNA binding. However, small spacing changes (addition or deletion of one to three residues) in the basic repeat eliminated DNA binding. These results argue for a bipartite DNA binding domain composed of direct repeats with a strict spacing and orientation. Surprisingly, some direct repeat mutations that inhibited DNA binding failed to show a corresponding inhibition of basal transcription, indicating compensating interactions of TFIID with other general factors. The implications of these and other recent results for TFIID structure, promoter recognition, and interactions with other factors are discussed.

Transcription factor TFIID induces DNA bending upon binding to the TATA element

The TATA box-binding factor TFIID plays a primary role in the process of transcription initiation by RNA polymerase II and its regulation by various gene-specific factors. Here we employ a permuted binding site/gel retardation assay with recombinant yeast and human TFIID to show that this factor induces DNA bending around the TATA element. These results are consistent with the presence of G + C-rich sequence elements flanking the consensus TATA element and led to the recently confirmed suggestion that TFIID interacts with the TATA element via the minor groove. They also raise the possibility that TFIID-induced bending might facilitate promoter interactions of other general factors in the preinitiation complex or interactions between general transcription factors and regulatory factors bound at upstream sites.

TFIID can be rate limiting in vivo for TATA-containing, but not TATA-lacking, RNA polymerase II promoters

We have studied the effect of exogenous expression of the basal transcription factor TFIID on the activities of several different TATA-containing and TATA-lacking promoters. Overexpression of TFIID from a transfected plasmid in Drosophila Schneider cells resulted in substantial concentration-dependent increases in expression from a cotransfected minimal TATA-containing promoter. Overexpression of TFIID activated expression from all TATA-containing promoters tested, with the maximum level of activation being inversely proportional to the strength of the promoter. In contrast, expression from TATA-less promoters was not enhanced, and could in fact be reduced, by increased expression of TFIID. Consistent with these findings overexpression of TFIID had opposite effects on Sp1-mediated activation observed from minimal synthetic promoters consisting of Sp1-binding sites and either a TATA box or initiator element. We discuss the significance of these results in terms of the role of TFIID in the initiation of transcription and as a possible regulatory target for expression from TATA-containing promoters, as well as the role TFIID may play in expression from TATA-less promoters.