A TATA-like sequence located downstream of the transcription initiation site is required for expression of an RNA polymerase II transcribed gene

Specific interaction between the nonphosphorylated form of RNA polymerase II and the TATA-binding protein

Fractionation of a transcription-competent HeLa cell extract on a column containing one copy of the heptamer repeat (YSPTSPS) present in the carboxy-terminal domain (CTD) of the largest subunit of RNA polymerase II resulted in the loss of transcriptional activity. Fractionation of the extracts on columns containing mutations of the heptamer repeat was without effect. Such transcriptionally inactive extracts regained their ability to specifically transcribe different class II promoters upon the addition of human TFIID, recombinant yeast TATA-binding protein (TBP), or proteins bound to the column. Fractionation of RNA polymerase II on columns containing human or yeast TBP resulted in the specific retention of the nonphosphorylated form of RNA polymerase II. The phosphorylated form of the enzyme was unable to interact with TBP. The specific interaction of RNA polymerase II with TBP was mediated by the CTD of RNA polymerase II.

The TATA-binding protein is required for transcription by all three nuclear RNA polymerases in yeast cells

Using temperature- and proteolytically sensitive derivatives to inactivate the function of the yeast TATA-binding protein (TBP) in vivo, we investigated the requirement of TBP for transcription by the three nuclear RNA polymerases in yeast cells. TBP is required for RNA polymerase II (pol II) transcription from promoters containing conventional TATA elements as well as functionally distinct promoters that lack TATA-like sequences. TBP is also required for transcription of the U6 snRNA and two different tRNA genes mediated by RNA pol III as well as transcription of ribosomal RNA mediated by RNA pol I. For all promoters tested, transcription decreases rapidly and specifically upon inactivation of TBP, strongly suggesting that TBP is directly involved in the transcription process. These observations suggest that TBP is required for transcription of all nuclearly encoded genes in yeast, although distinct molecular mechanisms are probably involved for the three RNA polymerase transcription machineries.

Eukaryotic topoisomerase II cleavage of parallel stranded DNA tetraplexes

A guanine-rich single-stranded DNA from the human immunoglobulin switch region was shown by Sen and Gilbert [Nature, (1988) 334, 364-366] to be able to self-associate to form a stable four-stranded parallel DNA structure. Topoisomerase II did not cleave the single-stranded DNA molecule. Surprisingly, the enzyme did cleave the same DNA sequence when it was annealed into the four-stranded structure. The two cleavage sites observed were the same as those found when this DNA molecule was paired with a complementary molecule to create a normal B-DNA duplex. These cleavages were shown to be protein-linked and reversible by the addition of salt, suggesting a normal topoisomerase II reaction mechanism. In addition, an eight-stranded DNA molecule created by the association of a complementary oligonucleotide with the four-stranded structure was also cleaved by topoisomerase II despite being resistant to restriction endonuclease digestion. These results suggest that a single strand of DNA may possess the sequence information to direct topoisomerase II to a binding site, but the site must be base paired in a proper manner to do so. This demonstration of the ability of a four-stranded DNA molecule to be a substrate for an enzyme further suggests that these DNA structures may be present in cells.

Evidence that USF can interact with only a single general transcription complex at one time

By in vitro analysis, the major late promoter (MLP) of adenovirus has been shown to be a simple promoter requiring two elements for efficient transcription: a minimal promoter element (MPE), where the general transcription factor-polymerase II complex binds, and a single functional upstream promoter element (UPE) which interacts with USF. Two hundred bases upstream of the MLP cap site and divergently oriented is the IVa2 promoter. This promoter has its own MPE but shares the MLP UPE, suggesting the possibility that these promoters are coordinately regulated. To determine mechanistically how this might function, we replaced the weak IVa2 minimal promoter with a strong MPE (from the viral E1A gene) and observed mutual inhibition of both promoters and unstable transcription factor binding. Only by duplication of the UPE could this inhibition be relieved. When tested independently, both promoters were shown to require the USF site for maximal activity. These results are compatible with a model in which USF can stably interact with only one transcription complex at a time. When two divergently oriented general transcription complexes compete efficiently for binding of USF, transcription is reduced to the same levels as if the USF site were absent.

Evidence that USF can interact with only a single general transcription complex at one time

By in vitro analysis, the major late promoter (MLP) of adenovirus has been shown to be a simple promoter requiring two elements for efficient transcription: a minimal promoter element (MPE), where the general transcription factor-polymerase II complex binds, and a single functional upstream promoter element (UPE) which interacts with USF. Two hundred bases upstream of the MLP cap site and divergently oriented is the IVa2 promoter. This promoter has its own MPE but shares the MLP UPE, suggesting the possibility that these promoters are coordinately regulated. To determine mechanistically how this might function, we replaced the weak IVa2 minimal promoter with a strong MPE (from the viral E1A gene) and observed mutual inhibition of both promoters and unstable transcription factor binding. Only by duplication of the UPE could this inhibition be relieved. When tested independently, both promoters were shown to require the USF site for maximal activity. These results are compatible with a model in which USF can stably interact with only one transcription complex at a time. When two divergently oriented general transcription complexes compete efficiently for binding of USF, transcription is reduced to the same levels as if the USF site were absent.

Transcription factor eUSF is an essential component of isolated transcription complexes on the duck histone H5 gene and it mediates the interaction of TFIID with a TATA-deficient promoter

We analysed the formation of transcription complexes on the H5 gene of the duck which is efficiently transcribed in HeLa cell extracts in vitro. Upon deletion of its TATA-box, the fidelity of transcription of the H5 gene is maintained, although the efficiency of this process is significantly reduced. Selective inactivation of TFIID in whole cell extracts and reconstitution experiments either with human recombinant TFIID or a protein fraction from duck erythrocytes enriched in TFIID show that transcription of the TATA-less H5 promoter nevertheless requires the protein TFIID. Screening of promoter elements which could indirectly mediate the interaction of TFIID with a TATA-less H5 promoter led to the identification of a sequence element located about 40 base-pairs downstream from the H5 initiation site that shows partial homology to the USF consensus sequence. In electrophoretic mobility shift and footprinting studies we demonstrated a specific interaction of the erythroid factor USF (eUSF) with this downstream element. By isolating active transcription complexes we found that all components required for correct initiation remain stably associated with the H5 promoter irrespective of the presence or absence of the TATA box. Moreover, the reconstitution of eUSF and TFIID-depleted transcription complexes with purified protein fractions demonstrate that not only TFIID but also eUSF essentially participates in complex formation even on H5 promoter mutations lacking the TATA-box. Mutual interactions between eUSF and TFIID appear to stabilize the binding of TFIID in the presence or absence of its proper binding site.

Molecular characterization of the lam locus and sequences involved in regulation by the AmdR protein of Aspergillus nidulans

The lam locus of Aspergillus nidulans consists of two divergently transcribed genes, lamA and lamB, involved in the utilization of lactams such as 2-pyrrolidinone. Both genes are under the control of the positive regulatory gene amdR and are subject to carbon and nitrogen metabolite repression. The lamB gene and the region between the two genes have been sequenced, and the start points of transcription have been determined. Within the lam locus are two sequences with homology to elements, required for AmdR regulation, found in the 5' regions of the coregulated genes amdS and gatA. In vitro and in vivo assays were used to investigate the lam and gatA regulatory elements. One of the three gatA elements and one of the two lam elements were shown to bind AmdR protein in vivo and activate transcription. With a gel shift mobility assay, in vitro binding of AmdR protein to the functional gatA element was detected. Both the functional gatA and lam boxes contain within them a CAAT sequence. In vitro binding analysis indicates that a CCAAT-specific factor(s) binds at these sequences, adjacent to or overlapping the AmdR protein-binding site.

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.

Molecular characterization of the lam locus and sequences involved in regulation by the AmdR protein of Aspergillus nidulans

The lam locus of Aspergillus nidulans consists of two divergently transcribed genes, lamA and lamB, involved in the utilization of lactams such as 2-pyrrolidinone. Both genes are under the control of the positive regulatory gene amdR and are subject to carbon and nitrogen metabolite repression. The lamB gene and the region between the two genes have been sequenced, and the start points of transcription have been determined. Within the lam locus are two sequences with homology to elements, required for AmdR regulation, found in the 5' regions of the coregulated genes amdS and gatA. In vitro and in vivo assays were used to investigate the lam and gatA regulatory elements. One of the three gatA elements and one of the two lam elements were shown to bind AmdR protein in vivo and activate transcription. With a gel shift mobility assay, in vitro binding of AmdR protein to the functional gatA element was detected. Both the functional gatA and lam boxes contain within them a CAAT sequence. In vitro binding analysis indicates that a CCAAT-specific factor(s) binds at these sequences, adjacent to or overlapping the AmdR protein-binding site.

Upstream box/TATA box order is the major determinant of the direction of transcription

Mammalian gene promoters for transcription by RNA polymerase II are typically organized in the following order: upstream sequence motif(s)/TATA box/initiation site. Here we report studies in which the order, orientation and DNA sequences of these three elements are varied to determine how these affect polarity of transcription. We have constructed promoters with an 'octamer' upstream sequence ATTTGCAT (or its complement ATGCAAAT) in combination with several different TATA boxes and initiation (cap) sites, and tested these promoters in transfection experiments with cultured cells. TATA boxes derived from the adenovirus major late promoter (TATAAAA), immunoglobulin kappa light chain (TTATATA) and heavy chain (TAAATATA) promoter functioned equally well or even better when inverted. Only the beta-globin TATA box (CATAAAA) was poorly active when inverted. In addition, a symmetrical TATA box (TATATATA) derived from a casein gene was very active. Our results suggest that the asymmetry of most TATA boxes (consensus TATAAAA) is not a primary determinant of the polarity of transcription. We also found that the initiation (cap) site, which usually consists of an adenine embedded in a pyrimidine-rich region (PyPyCAPyPyPyPyPy), was permissive towards sequence alterations; even a randomly composed sequence worked well. However, an inverted, hence purine-rich, cap site reduced transcript levels to 1/7th, as did an oligo G sequence. Irrespective of the presence of a cap site, the configuration: 'TATA box/octamer' yielded a strong leftward, rather than rightward transcription. From this, we conclude that the polarity of transcription is primarily determined by the linear order of an upstream sequence relative to a TATA box, rather than by the individual orientations of either of these two elements.

Transcription from a TATA-less promoter requires a multisubunit TFIID complex

In eukaryotes, the TATA box-binding protein (TBP) is responsible for nucleating assembly of the transcription initiation machinery. Here, we report that a TFIID complex containing TBP is essential for transcription even at a promoter that lacks a TATA box. Immunopurification of TFIID reveals that the active species in reconstituting TATA-less transcription is a multisubunit complex consisting of TBP and many TBP-associated factors (TAFs).

The initiator directs the assembly of a transcription factor IID-dependent transcription complex

Highly purified RNA polymerase II was found to be able to weakly recognize the initiator (Inr) present in the adenovirus IVa2 and major late promoters. The association of RNA polymerase II with the Inr was enhanced by the general transcription factors. The Inr was capable of directing the formation of a DNA-protein complex. Transcription competent complexes on the adenovirus major late and IVa2 promoters appear to be formed by alternative pathways mediated through the Inr and/or "TATA" motif. The presence of both motifs, however, is required for efficient transcription utilizing a discrete start site. Complexes formed at either site required transcription factor TFIID, the TATA binding protein. Consistent with this observation, a TFIID requirement was demonstrated for transcription from a mutant adenovirus major late promoter construct lacking a functional TATA motif.

Direct interaction between adenovirus E1A protein and the TATA box binding transcription factor IID

Adenovirus E1A has long been known to activate/repress cellular and viral transcription. The transcriptional activity of nuclear extracts was depleted after chromatography on immobilized E1A protein columns that specifically retained the transcription factor (TF) IID. Stronger direct interactions between E1A and human TFIID than between E1A and yeast TFIID suggest that the unique sequences of the human protein may be involved. We have demonstrated that this interaction occurs directly between bacterially produced E1A and bacterially produced human TFIID in a protein blot assay. We propose that E1A protein may transduce regulatory signals from upstream activators to basal elements of the transcriptional machinery by contacting TFIID.

Expression from the murine p53 promoter is mediated by factor binding to a downstream helix-loop-helix recognition motif

Expression of the p53 gene plays an important role in the regulation of cellular proliferation and malignant transformation. Overexpression of mutant forms of p53 is in fact a common feature of many transformed cells. Studies dealing with the transcriptional regulatory regions of the p53 gene indicate that, unlike most promoters transcribed by RNA polymerase II, the p53 promoter contains no TATA-like sequence upstream of the transcription start site. Here we demonstrate that the murine p53 promoter contains a cis-acting element that maps downstream to the transcription initiation site. The integrity of this element is required for high-level expression from the promoter in transformed cells. By DNase I protection and mobility-shift analysis, we show that a nuclear factor binds to this downstream element through the consensus recognition sequence for the helix-loop-helix (HLH)-containing proteins of the myc/MyoD family of transcriptional regulators. We propose that the activity of one or more members of this family of transcription factors is an important determinant in the expression of p53 and that at least one level of p53 overexpression in transformed cells may thus be due to aberrant expression of the relevant factor(s). Furthermore, the possibility that the regulation of expression of p53 occurs, in part, by means of a potential HLH-containing factor provides a possible mechanism for the suppression of proliferation by the MyoD family of transcriptional regulators.

Characterization of the murine Hox-2.3 promoter: involvement of the transcription factor USF (MLTF)

The murine homeobox-containing gene Hox-2.3 contains a basal promoter in a 210-bp region upstream of the transcription start site. In vitro studies of DNA-protein interactions in this region, and in a 1.3-kb upstream region which is known to play a role in tissue specific expression in vivo, led to the identification of DNA elements interacting with nuclear proteins from embryocarcinoma cells. Among the factors binding to the basal promoter is the upstream stimulating factor (USF), also known as major late transcription factor (MLTF). A single point mutation in its binding site abolishes binding in vitro and leads to 50% reduction of the transcriptional activity as measured in receptor gene experiments, showing that it is an activator of Hox-2.3 expression.

Factors involved in specific transcription by mammalian RNA polymerase II: role of transcription factors IIA, IID, and IIB during formation of a transcription-competent complex

Human transcription factor TFIID, the TATA-binding protein, was partially purified to a form capable of associating stably with the TATA motif of the adenovirus major late promoter. Binding of the human and yeast TFIID to the TATA motif was stimulated by TFIIA. TFIIA is an integral part of a complex capable of binding other transcription factors. A complex formed with human TFIID and TFIIA (DA complex) was specifically recognized by TFIIB. We found that TFIIB activity was contained in a single polypeptide of 32 kDa and that this polypeptide participated in transcription and was capable of binding to the DA complex to form the DAB complex. Formation of the DAB complex required TFIIA, TFIID, and sequences downstream of the transcriptional start site; however, the DA complex could be formed on an oligonucleotide containing only the adenovirus major late promoter TATA motif. Using anti-TFIIB antibodies and reagents that affect the stability of a transcription-competent complex, we found that yeast and human TFIID yielded DAB complexes with different stabilities.

Nucleotide sequence of murine PCNA: interspecies comparison of the cDNA and the 5' flanking region of the gene

Proliferating cell nuclear antigen (PCNA) RNA levels are regulated by transcription as well as changes in stability, in growing cells. We have cloned the murine PCNA cDNA and a fragment of the murine PCNA gene flanking the transcription initiation site. Comparison of the murine deduced amino acid sequence with the PCNA sequence from rat, human, Drosophila, Saccharomyces cerevisiae, and higher plants, reveals extensive homology between species. The homology is likely to be related to the fundamental role of PCNA as an auxiliary protein for DNA replication. Consensus sequences for transcriptional regulatory factors identified within 520 bp 5' of the cap site of the murine PCNA gene include: an inverted CCAAT site, an enhancer core element (EBP-1), three cAMP-response elements (CRE-BP), one AP-2 site, three Sp1 sites, and two octamer sequences. The first 20 bp of the transcriptional unit are homologous to an initiator element, which may direct transcription from RNA polymerase II in the absence of a TATAA box. The consensus elements in the murine PCNA gene are similar in sequence and/or location to elements identified in the genes for human, Drosophilia, and yeast PCNA.

Positive and negative transcriptional regulatory elements in the early H4 histone gene of the sea urchin, Strongylocentrotus purpuratus

The early H4 (EH4) histone gene of the sea urchin, Strongylocentrotus purpuratus, is shown to contain at least five positive-responding sequence elements and one negative-responding site which control the level of in vitro transcription in an embryonic nuclear extract. The positive acting elements are: 1) the UHF-1 region, located between -133 and -102 (the site of a strong footprint, due at least in part to the binding of an 85 kD protein factor termed UHF-1); 2) the H4 specific element (H4SE), situated between -62 and -39; 3) a sequence corresponding to a TATA box between -33 and -26 (TAACAATA); 4) the transcriptional initiation site; and 5) an internal sequence element found between +19 and +50. Deletion of, or base changes in, the UHF-1, H4SE, initiation, or internal sequence sites resulted in significant decreases in transcription. Base substitutions in the TATA-like sequence had much less effect, resulting in no more than a 2-fold decrease in transcription, and there was no evidence that alternative initiation sites are utilized in the mutant templates. The negative element (termed the UHF-3 site) is contained within a footprinted region between nucleotides -75 and -56. Base substitutions in this area result in templates that were transcribed at a level 1.2-2.0-fold higher than the wild-type gene. Transcription levels of double UHF-1/H4SE and UHF-1/INR mutants were those expected from additive effects of the individual mutations and there was no suggestion of synergism.

Factors involved in specific transcription by mammalian RNA polymerase II: role of transcription factors IIA, IID, and IIB during formation of a transcription-competent complex

Human transcription factor TFIID, the TATA-binding protein, was partially purified to a form capable of associating stably with the TATA motif of the adenovirus major late promoter. Binding of the human and yeast TFIID to the TATA motif was stimulated by TFIIA. TFIIA is an integral part of a complex capable of binding other transcription factors. A complex formed with human TFIID and TFIIA (DA complex) was specifically recognized by TFIIB. We found that TFIIB activity was contained in a single polypeptide of 32 kDa and that this polypeptide participated in transcription and was capable of binding to the DA complex to form the DAB complex. Formation of the DAB complex required TFIIA, TFIID, and sequences downstream of the transcriptional start site; however, the DA complex could be formed on an oligonucleotide containing only the adenovirus major late promoter TATA motif. Using anti-TFIIB antibodies and reagents that affect the stability of a transcription-competent complex, we found that yeast and human TFIID yielded DAB complexes with different stabilities.