A wide variety of DNA sequences can functionally replace a yeast TATA element for transcriptional activation

Two distinct factors bind to the rabbit uteroglobin TATA-box region and are required for efficient transcription

The rabbit uteroglobin gene is expressed in a variety of epithelial cell types like the lung Clara cells and the glandular and luminal epithelial cells of the endometrium. Expression in Clara cells is on a high constitutive level, whereas expression in the rabbit endometrium is under tight hormonal control. One important element of the rabbit uteroglobin gene mediating its efficient transcription in two epithelial cell lines from human endometrium (Ishikawa) and lung (NCI-H441) is its noncanonical TATA box (TACA). Here, we show that two factors (TATA core factor [TCF] and TATA palindrome factor [TPF]) different from the TATA-box binding protein bind to the DNA major groove at two adjacent sites within the uteroglobin TATA-box region and that one of them (TCF) is specifically expressed in cell lines derived from uteroglobin-expressing tissues. The binding sites for TCF and TPF, respectively, are both required for efficient transcription in Ishikawa and NCI-H441 cells. Mutation of the TACA box, which we show is a poor TATA box in functional terms, to a canonical TATA motif does not affect TCF and TPF binding. Therefore, we suggest that the function of the unusual cytosine could be to reduce rabbit uteroglobin expression in cells lacking TCF and that the interaction of TATA-box binding protein with the weak TACA site is facilitated in TCF- and TPF-positive cells.

Two distinct factors bind to the rabbit uteroglobin TATA-box region and are required for efficient transcription

The rabbit uteroglobin gene is expressed in a variety of epithelial cell types like the lung Clara cells and the glandular and luminal epithelial cells of the endometrium. Expression in Clara cells is on a high constitutive level, whereas expression in the rabbit endometrium is under tight hormonal control. One important element of the rabbit uteroglobin gene mediating its efficient transcription in two epithelial cell lines from human endometrium (Ishikawa) and lung (NCI-H441) is its noncanonical TATA box (TACA). Here, we show that two factors (TATA core factor [TCF] and TATA palindrome factor [TPF]) different from the TATA-box binding protein bind to the DNA major groove at two adjacent sites within the uteroglobin TATA-box region and that one of them (TCF) is specifically expressed in cell lines derived from uteroglobin-expressing tissues. The binding sites for TCF and TPF, respectively, are both required for efficient transcription in Ishikawa and NCI-H441 cells. Mutation of the TACA box, which we show is a poor TATA box in functional terms, to a canonical TATA motif does not affect TCF and TPF binding. Therefore, we suggest that the function of the unusual cytosine could be to reduce rabbit uteroglobin expression in cells lacking TCF and that the interaction of TATA-box binding protein with the weak TACA site is facilitated in TCF- and TPF-positive cells.

TBP-DNA interactions in the minor groove discriminate between A:T and T:A base pairs

In this report, we test the hypothesis that TBP binds DNA promiscuously due to its manner of recognition of the DNA minor groove. The experiment performed was to select TBP-binding sequences from a pool of random double stranded oligonucleotides. Sixty two clones from this pool were sequenced. Surprisingly, the results show that TBP has a marked preference for stably binding one sequence (TATATAA) over all others, yet only four classes of TATA box were selected. The features of the selected sequences allow definition of a binding consensus for TBP. The DNA binding properties of TBP to the four TATA variants was examined, the results being in accord with the observed selection frequencies. However, the nature of TBP-DNA binding is strongly affected by ionic strength. We infer that recognition of DNA via the minor groove can be highly selective even where A:T and T:A discrimination is required. Models for how this might be accomplished are discussed.

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.

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.

Redundant regulatory elements account for the developmental control of a ribosomal protein gene of Dictyostelium discoideum

In Dictyostelium discoideum, ribosomal protein genes along with other growth specific genes appear to be coordinately regulated, primarily in response to differences in the translational capacity of developing versus growing cells. In particular, expression of the members of this large class of genes is rapidly and dramatically deactivated when the developmental program is initiated and growth and division cease. In order to understand the mechanisms behind the deactivation event and how it is coupled to the transition from growth to development, we have analyzed the promoter of the V18 gene, a ribosomal protein gene characteristic of this class of growth specific genes. We have delineated three discrete regions involved in the transcription and regulation of the V18 gene. A initiator region which appears to function in a TATA-independent manner was required for transcription and for establishing start site utilization. Two regions upstream of this were defined, both of which were found to independently confer proper developmental regulation.

The yeast DOA4 gene encodes a deubiquitinating enzyme related to a product of the human tre-2 oncogene

Modification of specific intracellular proteins by ubiquitin targets them for degradation. We describe a yeast enzyme, Doa4, that is integral to the degradation of ubiquitinated proteins and is required in diverse physiological processes. Doa4 appears to function late in the proteolytic pathway by cleaving ubiquitin from substrate remnants still bound to protease. The human tre-2 oncogene encodes a deubiquitinating enzyme similar to Doa4, indicating a role for the ubiquitin system in mammalian growth control.

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.

Analysis of regulatory elements flanking metallothionein genes in Cd-tolerant fish (pike and stone loach)

From genomic libraries constructed for both pike and stone loach, clones were isolated containing the metallothionein genes from these two species of cadmium-tolerant fish. A single copy metallothionein gene was identified in each species by Southern blot analysis. Sequencing revealed that each gene consisted of three exons followed by polyadenylation signals at the 3' end. In the 5' flanking region, putative metal responsive elements were identified both close to the transcription start site and clustered distally approx. 500 bp upstream. Neither gene locus showed any homology with the glucocorticoid or interferon responsive elements that have been identified in mammalian species. The significance of the absence of such responsive elements and their replacement by additional metal responsive elements in the same location of the 5'-flanking region of the MT genes is discussed in relation to the organisation of the MT gene loci in (the Cd-sensitive) rainbow trout and higher mammalian species.

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.

A TBP-containing multiprotein complex (TIF-IB) mediates transcription specificity of murine RNA polymerase I

TIF-IB is a transcription factor which interacts with the mouse ribosomal gene promoter and nucleates the formation of an initiation complex containing RNA polymerase I (Pol I). We have purified this factor to near homogeneity and demonstrate that TIF-IB is a large complex (< 200 kDa) which contains several polypeptides. One of the subunits present in this protein complex is the TATA-binding protein (TBP) as revealed by copurification of TIF-IB activity and TBP over different chromatographic steps including immunoaffinity purification. In addition to TBP, three tightly associated proteins (TAFs-I) with apparent molecular weights of 95, 68, and 48 kDa are contained in this multimeric complex. This subunit composition is similar--but not identical--to the analogous human factor SL1. Depletion of TBP from TIF-IB-containing fractions by immunoprecipitation eliminates TIF-IB activity. Neither TBP alone nor fractions containing other TBP complexes are capable of substituting for TIF-IB activity. Therefore, TIF-IB is a unique complex with Pol I-specific TAFs distinct from other TBP-containing complexes. The identification of TBP as an integral part of the murine rDNA promoter-specific transcription initiation factor extends the previously noted similarity of transcriptional initiation by the three nuclear RNA polymerases and underscores the importance of TAFs in determining promoter specificity.

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.

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.

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.

Molecular genetics in Saccharomyces kluyveri: the HIS3 homolog and its use as a selectable marker gene in S. kluyveri and Saccharomyces cerevisiae

We cloned the Saccharomyces kluyveri HIS3 homolog, k-HIS3, and made a partial deletion of the gene. The k-HIS3 gene complemented a HIS3 deletion in S. cerevisiae. The DNA sequences of the open reading frames (ORFs) of the HIS3 homologs are 70% identical at the DNA level and 83% identical at the deduced amino acid level. The ORF upstream of the k-HIS3 gene is related to the PET56 gene of S. cerevisiae found upstream of the HIS3 gene of S. cerevisiae. The ORF downstream from the k-HIS3 gene is not related to the DED1 gene found downstream of the HIS3 gene in S. cerevisiae.

A REB1-binding site is required for GCN4-independent ILV1 basal level transcription and can be functionally replaced by an ABF1-binding site

The ILV1 gene of Saccharomyces cerevisiae encodes the first committed step in isoleucine biosynthesis and is regulated by general control of amino acid biosynthesis. Deletion analysis of the ILV1 promoter revealed a GC-rich element important for the basal level expression. This cis-acting element, called ILV1BAS, is functional independently of whether GCN4 protein is present. Furthermore, unlike the situation at HIS4, the magnitude of GCN4-mediated derepression is independent of ILV1BAS. The element has homology to the consensus REB1-binding sequence CGGGTARNNR. Gel retardation assays showed that REB1 binds specifically to this element. We show that REB1-binding sites normally situated in the SIN3 promoter and in the 35S rRNA promoter can substitute for the ILV1 REB1 site. Furthermore, a SIN3 REB1 site containing a point mutation that abolishes REB1 binding does not support ILV1 basal level expression, suggesting that binding of REB1 is important for the control of ILV1 basal level expression. Interestingly, an ABF1-binding site can also functionally replace the ILV1 REB1-binding site. A mutated ABF1 site that displays a very low affinity for ABF1 does not functionally replace the ILV1 REB1 site. This suggests that ABF1 and REB1 may have related functions within the cell. Although the REB1-binding site is required for the ILV1 basal level expression, the site on its own stimulates transcription only slightly when combined with the CYC1 downstream promoter elements, indicating that another ILV1 promoter element functions in combination with the REB1 site to control high basal level expression.

ACR1, a yeast ATF/CREB repressor

Members of the mammalian ATF/CREB family of transcription factors, which are associated with regulation by cyclic AMP and viral oncogenes, bind common DNA sequences (consensus TGACGTCA) via a bZIP domain. In the yeast Saccharomyces cerevisiae, ATF/CREB-like sequences confer either repression or activation of transcription, depending on the promoter context. By isolating mutations that alleviate the repression mediated by ATF/CREB sites, we define a new yeast gene, ACR1, which encodes an ATF/CREB transcriptional repressor. ACR1 contains a bZIP domain that is necessary for homodimer formation and specific DNA binding to an ATF/CREB site. Within the bZIP domain, ACR1 most strongly resembles the mammalian cyclic AMP-responsive transcriptional regulators CREB and CREM; it is less similar to GCN4 and YAP1, two previously described yeast bZIP transcriptional activators that recognize the related AP-1 sequence (consensus TGACTCA). Interestingly, deletion of the ACR1 gene causes increased transcription through ATF/CREB sites that does not depend on GCN4 or YAP1. Moreover, extracts from acr1 deletion strains contain one or more ATF/CREB-like DNA-binding activities. These genetic and biochemical observations suggest that S. cerevisiae contains a family of ATF/CREB proteins that function as transcriptional repressors or activators.

V-src-induced-transcription of the avian clusterin gene

We have isolated the avian gene T64 corresponding to the mammalian clusterin, on the basis of high accumulation of its template mRNA in cells infected with oncogenic retroviruses. Since the clusterin was shown to have a protective effect against the immune system, its induction by oncogenic viruses is of major biological importance. The unique, short 5 kb-long T64 genomic locus is inactive in normal quail embryo fibroblasts in primary culture whereas it shows a high transcriptional activity after transformation by the Rous sarcoma virus. The 963 bp-long 5' flanking region is sufficient to drive the transcription of the chloramphenicol acetyltransferase reporter gene in a thermodependent manner when a thermosensitive version of pp60v-src is used. Deletion and point mutation analyses of the promoter show that the v-src response requires at least two separate elements: PUR and AP-1, located respectively at positions -167 to -152 and -25 to -19 relative to the single transcription initiation site. In addition, the binding of specific nuclear factors to these responsive elements correlates with the T64 promoter activation.

Mechanism of TATA-binding protein recruitment to a TATA-less class III promoter

The TATA-binding protein (TBP) is required for transcription by RNA polymerase III (pol III), even though many pol III templates, such as the adenovirus VA1 gene, lack a consensus TATA box. We show that TBP alone does not form a stable, productive interaction with VA1 DNA. However, it can be incorporated into an initiation complex if the other class III basal factors, TFIIIB and TFIIIC, are also present. TFIIIB can associate with the evolutionarily conserved C-terminal domain of TBP in the absence of DNA or TFIIIC, suggesting that TFIIIB exists in solution as a complex with TBP. The stable association of TBP with an essential component of the pol III transcription apparatus may account for the ability of TATA-less class III genes to recruit TBP.

The TATA-binding protein and associated factors are components of pol III transcription factor TFIIIB

RNA polymerases I, II, and III require the TATA-binding protein (TBP) to initiate promoter-specific transcription. We have separated HeLa TBP into four phosphocellulose fractions that elicit polymerase specificity in supplying TBP activity to TBP-depleted pol II and pol III transcription reactions. Polymerase specificity might arise in part through distinct TBP-associated factors (TAFs), which have recently been identified in pol I and II transcription. However, the requirement for pol III TAFs has not been established. Here we show that classical pol III transcription involves a minimum of two novel TAFs: TAF-172 and TAF-L. Not only does TAF-172 activate pol III transcription, but it also inhibits the binding of TBP to the TATA box, thereby repressing pol II transcription. The TBP-TAF-172-TAF-L complex can replace TFIIIB both in transcription reactions reconstituted with TFIIIC and in template commitment assays. Thus SL1, TFIID, and TFIIIB might be functionally similar TBP-TAF complexes that direct pol I, II, and III transcription, respectively.

A GC box in the bidirectional promoter is essential for expression of the human dihydrofolate reductase and mismatch repair protein 1 genes

The human dihydrofolate reductase and mismatch repair protein 1 genes are organized in a head-to-head configuration separated by an 88 base-pair segment and directed by a bidirectional promoter. In vivo transient assays of the site directed mutant promoters using firefly luciferase as a reporter showed that an AT-rich sequence, ACAAATA, in the GC-rich promoter sequence is not required for transcription. However, two out of four GC boxes were shown to function as bidirectional positive regulatory elements. Among them, a GC box at the midpoint of the region between the two initiation sites is essential for supporting minimal bidirectional activity.

ACR1, a yeast ATF/CREB repressor

Members of the mammalian ATF/CREB family of transcription factors, which are associated with regulation by cyclic AMP and viral oncogenes, bind common DNA sequences (consensus TGACGTCA) via a bZIP domain. In the yeast Saccharomyces cerevisiae, ATF/CREB-like sequences confer either repression or activation of transcription, depending on the promoter context. By isolating mutations that alleviate the repression mediated by ATF/CREB sites, we define a new yeast gene, ACR1, which encodes an ATF/CREB transcriptional repressor. ACR1 contains a bZIP domain that is necessary for homodimer formation and specific DNA binding to an ATF/CREB site. Within the bZIP domain, ACR1 most strongly resembles the mammalian cyclic AMP-responsive transcriptional regulators CREB and CREM; it is less similar to GCN4 and YAP1, two previously described yeast bZIP transcriptional activators that recognize the related AP-1 sequence (consensus TGACTCA). Interestingly, deletion of the ACR1 gene causes increased transcription through ATF/CREB sites that does not depend on GCN4 or YAP1. Moreover, extracts from acr1 deletion strains contain one or more ATF/CREB-like DNA-binding activities. These genetic and biochemical observations suggest that S. cerevisiae contains a family of ATF/CREB proteins that function as transcriptional repressors or activators.

A constitutive enhancer in the bovine papillomavirus upstream regulatory region shares genetic elements with the viral P1 promoter

The bovine papillomavirus upstream regulatory region represents a common element in the regulation of transcription from the five early viral promoters. We have determined the sequences required for transcription from the viral P1 promoter, which is located at the 5' end of the upstream regulatory region. In vitro transcription from P1 requires a 123-bp fragment (nucleotides 7153 to 7275; -33 to +90) consisting of an upstream TATA-like sequence as well as an unidentified protein which binds to sequences immediately downstream of the initiation site. In vivo, this promoter requires additional downstream sequences (to position +160; nucleotide 7345) for maximal activity but does not require any additional DNA sequence upstream of a putative TATA box. Four regions within the downstream sequence from +9 to +160 are protected from DNase I digestion by proteins present in a HeLa cell extract. The presence of these sites correlates with the level of P1 activity. A constitutive enhancer maps to this same region, and mutations in this enhancer have been shown to affect downstream promoters. Deletion analysis indicates that the same sequences are required by both the P1 promoter and the constitutive enhancer, suggesting that the same proteins function in both activities.

A REB1-binding site is required for GCN4-independent ILV1 basal level transcription and can be functionally replaced by an ABF1-binding site

The ILV1 gene of Saccharomyces cerevisiae encodes the first committed step in isoleucine biosynthesis and is regulated by general control of amino acid biosynthesis. Deletion analysis of the ILV1 promoter revealed a GC-rich element important for the basal level expression. This cis-acting element, called ILV1BAS, is functional independently of whether GCN4 protein is present. Furthermore, unlike the situation at HIS4, the magnitude of GCN4-mediated derepression is independent of ILV1BAS. The element has homology to the consensus REB1-binding sequence CGGGTARNNR. Gel retardation assays showed that REB1 binds specifically to this element. We show that REB1-binding sites normally situated in the SIN3 promoter and in the 35S rRNA promoter can substitute for the ILV1 REB1 site. Furthermore, a SIN3 REB1 site containing a point mutation that abolishes REB1 binding does not support ILV1 basal level expression, suggesting that binding of REB1 is important for the control of ILV1 basal level expression. Interestingly, an ABF1-binding site can also functionally replace the ILV1 REB1-binding site. A mutated ABF1 site that displays a very low affinity for ABF1 does not functionally replace the ILV1 REB1 site. This suggests that ABF1 and REB1 may have related functions within the cell. Although the REB1-binding site is required for the ILV1 basal level expression, the site on its own stimulates transcription only slightly when combined with the CYC1 downstream promoter elements, indicating that another ILV1 promoter element functions in combination with the REB1 site to control high basal level expression.

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.

Yeast transcription factor IID participates in cell-free transcription of a mammalian ribosomal protein TATA-less promoter

We analysed transcription of the gene for the ribosomal protein (rp) L32 of the mouse, which is transcribed in mouse L1210 nuclear extracts in vitro. The rpL32 gene lacks a canonical TATA box. Hence it has been suggested that this gene has an alternative transcription pathway not requiring transcription factor IID (TFIID). Selective inactivation of TFIID in nuclear extract completely abolished the transcription of rpL32 in vitro. Selective inactivation was restored by the addition of cloned and purified yeast TFIID (yTFIID), indicating that this TATA-less rpL32 promoter utilizes TFIID for its transcription initiation. Furthermore, addition of an oligonucleotide-containing TATA sequence interfered with the rpL32 transcription and this was overcome by the addition of yTFIID. To further examine the stage of involvement of TFIID in rpL32 transcription, TATA oligonucleotide was added to nuclear extract before and after the formation of the transcription complex. The results reveal that TFIID associates with the pre-initiation complex and that this complex is largely resistant to added TATA oligonucleotide. Our results show, for the first time, that the TATA-less rpL32 gene utilizes TFIID for transcription initiation.

Cloning and expression of the Acanthamoeba castellanii gene encoding transcription factor TFIID

We have cloned and characterized the cDNA encoding transcription factor TFIID from the eukaryote, Acanthamoeba castellanii. The gene occurs as a single species, encodes one mRNA and, presumably, a single protein. A. castellanii TFIID contains two recognizable domains, a nonconserved N-terminal domain and a highly conserved C-terminal domain. Similarities between the amino acid (aa) sequences of TFIID from several organisms are also found within the N-terminal 78 aa, suggesting a potential role in TFIID function. Full-length or truncated A. castellanii TFIID produced in Escherichia coli binds to a TATA box and is able to activate transcription in a TFIID-depleted HeLa cell extract, but the C-terminal 180-aa domain was found to be less efficient in these reactions.

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.

STP1, a gene involved in pre-tRNA processing, encodes a nuclear protein containing zinc finger motifs

STP1 is an unessential yeast gene involved in the removal of intervening sequences from some, but not all, families of intervening sequence-containing pre-tRNAs. Previously, we proposed that STP1 might encode a product that generates pre-tRNA conformations efficiently recognized by tRNA-splicing endonuclease. To test the predictions of this model, we have undertaken a molecular analysis of the STP1 gene and its products. The STP1 locus is located on chromosome IV close to at least two other genes involved in RNA splicing: PRP3 and SPP41. The STP1 open reading frame (ORF) could encode a peptide of 64,827 Da; however, inspection of putative transcriptional and translational regulatory signals and mapping of the 5' ends of mRNA provide evidence that translation of the STP1 ORF usually initiates at a second AUG to generate a protein of 58,081 Da. The STP1 ORF contains three putative zinc fingers. The first of these closely resembles both the DNA transcription factor consensus and the Xenopus laevis p43 RNA-binding protein consensus. The third motif more closely resembles the fingers found in spliceosomal proteins. Employing antisera to the endogenous STP1 protein and to STP1-LacZ fusion proteins, we show that the STP1 protein is localized to nuclei. The presence of zinc finger motifs and the nuclear location of the STP1 protein support the model that this gene product is involved directly in pre-tRNA splicing.

STP1, a gene involved in pre-tRNA processing, encodes a nuclear protein containing zinc finger motifs

STP1 is an unessential yeast gene involved in the removal of intervening sequences from some, but not all, families of intervening sequence-containing pre-tRNAs. Previously, we proposed that STP1 might encode a product that generates pre-tRNA conformations efficiently recognized by tRNA-splicing endonuclease. To test the predictions of this model, we have undertaken a molecular analysis of the STP1 gene and its products. The STP1 locus is located on chromosome IV close to at least two other genes involved in RNA splicing: PRP3 and SPP41. The STP1 open reading frame (ORF) could encode a peptide of 64,827 Da; however, inspection of putative transcriptional and translational regulatory signals and mapping of the 5' ends of mRNA provide evidence that translation of the STP1 ORF usually initiates at a second AUG to generate a protein of 58,081 Da. The STP1 ORF contains three putative zinc fingers. The first of these closely resembles both the DNA transcription factor consensus and the Xenopus laevis p43 RNA-binding protein consensus. The third motif more closely resembles the fingers found in spliceosomal proteins. Employing antisera to the endogenous STP1 protein and to STP1-LacZ fusion proteins, we show that the STP1 protein is localized to nuclei. The presence of zinc finger motifs and the nuclear location of the STP1 protein support the model that this gene product is involved directly in pre-tRNA splicing.

DNA sequences at and between the GC and TATA boxes: potential DNA looping and spatial juxtapositioning of the protein factors

Regulation of gene expression in eukaryotes involves a complex assembly of DNA recognition sequence elements and their respective protein factors. The upstream promoter/enhancer sequences are position and orientation independent. Despite their variable distances from the TATA box and transcription start site, interaction between the protein activators and TATA general transcription factors takes place, enabling induced levels of transcription initiation. Here the intervening sequences between the GC and TATA boxes are examined as functions of their lengths. Regardless of the substantial differences in the spacer sizes, similar mono and dinucleotide distributions are noted. Purine-purine base pair steps, except for AA, are more frequent at and near the GC box in the 5' ends of the loops than in their 3' ends. Pyrimidine-pyrimidine base pair steps, except for TT behave similarly. AT and TA (as well as AA and TT) are more frequent in the 3' ends of the loops near the TATA. Examination of these distributions, as well as of the sequences composing the GC and TATA boxes indicates that the DNA in the upstream part of the loop is more rigid, whereas the downstream regions are far more flexible. The flexibility of the general TATA region may afford correct spatial juxtapositioning of the proteins with respect to each other, enabling interactions between the activators and the general transcription factors.

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.

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.

Cis- and trans-acting elements required for constitutive and cytokine-regulated expression of the mouse complement C3 gene

The third component of complement (C3) is an important mediator of inflammation. Murine and human genomic cosmid clones were isolated, characterized and sequenced 5' to the complement C3 gene transcriptional initiation sites to determine cis elements that participate in constitutive and regulated C3 gene expression. The murine and human 5' flanking regions are 51% identical overall, with positions -36 to -1 and -146 to -68 showing 80% identity. Four TATA boxes were identified upstream of the murine transcriptional initiation site, but deletion and transfection analysis using reporter gene constructs in HepG2 cells indicated that only the TATA element at position -30, together with sequences -395 to -111, are essential for constitutive expression of murine C3 in hepatocytes. Deletion analysis also suggested that sequences between -1457 and -800 contain regulatory elements that are involved in suppressing basal expression. Sequences between -90 to -41 confer both enhancer activity and interleukin-1/-6 (IL-1/IL-6)-responsiveness. Mutation analyses showed that both sequences between -88 and -83 and -77 to -72 are essential for enhancer activity and responsiveness to IL-1, but only sequences between -88 and -83 are necessary for IL-6-responsiveness. A gel-retardation assay showed that several nucleoproteins, perhaps of the C/EBP family, from HepG2 cells bound to sequences between -88 to -83. Collectively, these results localize cis-acting elements involved in constitutive and IL-1/IL-6-regulated murine C3 gene expression and provide evidence for specific transacting factors.

A role for the TATA-box-binding protein component of the transcription factor IID complex as a general RNA polymerase III transcription factor

The major class of vertebrate genes transcribed by RNA polymerase (EC 2.7.7.6) III, which includes 5S rRNA genes, tRNA genes, and the adenovirus VA genes, is characterized by split internal promoters and no absolute dependence upon specific upstream sequences. Fractionation experiments have shown that transcription of such genes requires two general RNA polymerase III-specific factors, TFIIIB and TFIIIC. We now demonstrate that a third general factor is also employed by these genes. This is the TATA-box-binding protein originally identified as being a component of the general RNA polymerase II transcription factor TFIID. This protein is involved in the transcription by RNA polymerase III of every template tested, even though the promoters of VA and most vertebrate tRNA and 5S rRNA genes do not contain recognizable TATA elements.

Yeast and human TFIID with altered DNA-binding specificity for TATA elements

TFIID is the highly conserved, but species-specific, component of the RNA polymerase II transcription machinery that binds specifically to the TATA element (consensus TATAAA). Using a genetic selection, we isolated an altered specificity derivative of yeast TFIID that permits transcription from promoters containing a mutated TATA element (TGTAAA). Biochemical analysis indicates that this TFIID derivative has specifically gained the ability to bind TGTAAA efficiently. The mutant protein contains three substitutions within a 12 amino acid region; two of these are necessary and primarily responsible for the altered specificity. An analogous version of human TFIID, generated by introducing the same amino acid substitutions in the corresponding region of the protein, can support basal and GCN4-activated transcription in yeast cells from a TGTAAA-containing promoter. These results define a surface of TFIID that directly interacts with the TATA element, and they indicate that human TFIID can respond to acidic activator proteins in conjunction with the other components of the yeast transcription machinery.

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.

Functional roles for the TATA promoter and enhancers in basal and Tat-induced expression of the human immunodeficiency virus type 1 long terminal repeat

We have analyzed the contributory role of the human immunodeficiency virus type 1 (HIV-1) promoter and enhancers in basal and Tat-induced transcription. We found that a minimal promoter competent for basal expression is contained within sequences spanning nucleotides -43 to +80. Basal expression from this HIV-1 promoter was boosted more by the additional presence of the NF-kappa B elements than by the Sp1 elements. The minimal long terminal repeat promoter (-43 to +80), while having an intact TAR sequence, was not Tat inducible. However, the simple addition of short synthetic enhancer motifs (AP1, Oct, Sp1, and NF-kappa B) conferred Tat responsiveness. This ability to respond to Tat was in part dependent on the presence of the HIV-1 promoter. Changing the HIV-1 TATA to other eucaryotic TATA or non-TATA initiators minimally affected basal expression but altered Tat inducibility. Our findings suggest a specific context of functional promoter and enhancer elements that is optimal for Tat trans activation of the HIV-1 long terminal repeat. Our results do not allow conclusions about whether Tat acts at the level of initiation or at the level of elongation to be drawn.