A yeast activity can substitute for the HeLa cell TATA box factor

DNA-binding and transcriptional properties of human transcription factor TFIID after mild proteolysis

The existence of separable functions within the human class II general transcription factor TFIID was probed for differential sensitivity to mild proteolytic treatment. Independent of whether TFIID was bound to DNA or free in solution, partial digestion with either one of a variety of nonspecific endoproteases generated a protease-resistant protein product that retained specific DNA recognition, as revealed by DNase I footprinting. However, in contrast to native TFIID, which interacts with the adenovirus major late (ML) promoter over a very broad DNA region, partially proteolyzed TFIID interacted with only a small region of the ML promoter immediately surrounding the TATA sequence. This novel footprint was very similar to that observed with the TATA factor purified from yeast cells. Partially proteolyzed human TFIID could form stable complexes that were resistant to challenge by exogenous templates. It could also nucleate the assembly of transcription complexes on the ML promoter with an efficiency comparable to that of native TFIID, yielding similar levels of transcription initiation. These results suggest a model in which the human TFIID protein is composed of at least two different regions or polypeptides: a protease-resistant "core," which by itself is sufficient for promoter recognition and basal transcriptional levels, and a protease-sensitive "tail," which interacts with downstream promoter regions and may be involved in regulatory processes.

Mechanism of transcriptional activation by Sp1: evidence for coactivators

In reconstituted reactions, Sp1 stimulates transcription at TATA-containing promoters in the presence of semipurified TFIID fractions from either human or Drosophila cells, but is unable to do so when these fractions are replaced by purified, cloned Drosophila or yeast TFIID. Our findings with Sp1 and CTF suggest that partially purified TFIID fractions from human and Drosophila cells contain coactivators that are dispensable for basal transcription but are required as molecular adaptors between trans-activators and the general transcription initiation machinery. Experiments using cloned TFIID proteins suggest that these coactivators function through the amino-terminal portion of TFIID and that coactivator-TFIID interactions are species specific. At promoters lacking a TATA box, an additional activity distinct from coactivators is required for Sp1 activation of transcription.

Cloning of a transcriptionally active human TATA binding factor

Transcription factor IID (TFIID) binds to the TATA box promoter element and regulates the expression of most eukaryotic genes transcribed by RNA polymerase II. Complementary DNA (cDNA) encoding a human TFIID protein has been cloned. The human TFIID polypeptide has 339 amino acids and a molecular size of 37,745 daltons. The carboxyl-terminal 181 amino acids of the human TFIID protein shares 80% identity with the TFIID protein from Saccharomyces cerevisiae. The amino terminus contains an unusual repeat of 38 consecutive glutamine residues and an X-Thr-Pro repeat. Expression of DNA in reticulocyte lysates or in Escherichia coli yielded a protein that was competent for both DNA binding and transcription activation.

Analysis of structure-function relationships of yeast TATA box binding factor TFIID

A systematic series of N-terminal, C-terminal, and internal deletion mutants of S. cerevisiae TFIID were expressed in vitro and tested for TATA box binding and basal level transcription activities using, respectively, DNA mobility shift and in vitro transcription assays. The domains responsible for these activities were colocalized to a surprisingly large region containing C-terminal residues 63-240. This region was noted previously to contain potentially interesting structural motifs (central basic core, direct repeats, and sigma factor homology) and, more recently, to be highly conserved among TFIID from different species. Deletion mutant cotranslation studies revealed that TFIID binds DNA as a monomer. The implications of these results for TFIID structure and function are discussed.

Direct and selective binding of an acidic transcriptional activation domain to the TATA-box factor TFIID

The potent transactivation domain of the herpes simplex virion protein VP16 was used as a column ligand for affinity chromatography. VP16 binds strongly and highly selectively to the human and yeast TATA box-binding factors. Our results imply that the principal target for acidic activation domains is the TATA-box factor TFIID.

Purification of the upstream element factor of the adenovirus-2 major late promoter from HeLa and yeast by sequence-specific DNA affinity chromatography

The purification to homogeneity of the Adenovirus-2 major late promoter (MLP) upstream element factor (UEF), a sequence specific transcription factor, which binds to upstream elements of various class B (II) genes, is reported. The protein was purified from HeLa cells and also from the yeast Saccharomyces cerevisiae, by using sequence-specific DNA affinity chromatography. The human (UEFh, 45,000 dalton) and the yeast (UEFy, 60,000 dalton) proteins protect the same sequences over the MLP-IVa2 intergenic region: the MLP-UE (from nucleotide -49 to -67) and the IVa2-UE (from nucleotide -98 to -122 relative to the MLP initiation site). Both proteins have a higher affinity for the MLP-UE than for the IVa2-UE.

Transcription factor IIA of wheat and human function similarly with plant and animal viral promoters

Eucaryotic transcription initiation by RNA polymerase II involves protein:DNA interactions during the formation of a transcription complex. In addition to RNA polymerase II there are at least five other general transcription factors necessary for initiation with the adenovirus major late promoter. One of these, TFIIA, is involved in the earliest events during transcription complex assembly. We have purified TFIIA from wheat germ and characterized it in an in vitro transcription system. Wheat TFIIA is a single polypeptide of Mr approximately 35 kd which functionally replaces human (HeLa) TFIIA to form a wheat/HeLa transcription system. [This polypeptide can be eluted from a SDS-polyacrylamide gel, refolded to a native conformation, and will function as wheat TFIIA in the heterologous system.] The heterologous system requires a lower optimal incubation temperature than the HeLa system. Biochemical characterization, using the adenovirus major late promoter, indicates that transcription reaction parameters for both wheat and HeLa TFIIA are similar but the kinetics of transcription for both TFIIAs are somewhat dissimilar. A plant viral promoter, the cauliflower mosaic virus 35S promoter, accurately and efficiently directs in vitro transcription in both the wheat/HeLa and HeLa systems with identical transcription kinetics. We conclude that TFIIA function has been conserved during evolution.

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

We created a library of DNA molecules in which the required TATA element of a yeast gal-his3 promoter is replaced by random-sequence oligomers averaging 16 bp in length. Surprisingly, 1% of such random sequences functionally replace the native yeast TATA element. In many cases, sequences completely unrelated to the consensus TATA element (TATAAA) stimulate transcription with equal or increased efficiency. Transcription mediated by these synthetic elements requires GAL4 and is initiated from normal his3 initiation sites, suggesting that it occurs by a mechanism indistinguishable from that involving wild-type TATA elements. Many, but not all, of these elements act as substrates for yeast TFIID in reconstituted transcription reactions in vitro. These observations indicate that yeast TFIID can stimulate transcription from TATA elements whose sequences differ from the consensus, and they suggest the possibility of alternative factors that may provide a related function for transcriptional activation.

Purification and lipid-layer crystallization of yeast RNA polymerase II

Yeast RNA polymerase II was purified to homogeneity by a rapid procedure involving immunoaffinity chromatography. The purified enzyme contained 10 subunits, as reported for conventional preparations, but with no detectable proteolysis of the largest subunit. In assays of initiation of transcription at the yeast CYC1 promoter, the enzyme complemented the deficiency of an extract from a strain that produces a temperature-sensitive polymerase II. Mammalian RNA polymerase II was inactive in this initiation assay. The purified yeast enzyme formed two-dimensional crystals on positively charged lipid layers, as previously found for Escherichia coli RNA polymerase holoenzyme. Image analysis of electron micrographs of crystals in negative stain, which diffracted to about 30-A resolution, showed protein densities of dimensions consistent with those of single polymerase molecules.

Mutations that increase the activity of a transcriptional activator in yeast and mammalian cells

Activating region I of GAL4 protein is a stretch of amino acids, positioned adjacent to the DNA-binding region, that activates transcription in yeast and, as we show here, in mammalian cells. Here we describe mutations located throughout a 65-amino acid region that increase the activation function of region I. Most of these mutations replace positively charged amino acids in the region with neutral ones, although we also describe substitutions at one position that do not alter the charge of the region. Mutations of region I that alter the activation function in yeast have similar effects on activation when assayed in mammalian cells. When individual mutations that raise the acidity of the activating region are recombined, the activities of the mutant proteins increase with increasing negative charge in both yeast and mammalian cells. These results extend and modify the correlation between acidity and activation and suggest that the requirements for a strong activating region are conserved in yeast and mammals.

In vitro transcription from cauliflower mosaic virus promoters by a cell-free extract from tobacco cells

We have studied transcription from the cauliflower mosaic virus 19S and 35S promoters in a cell-free system derived from tobacco cells in suspension culture. While a whole-cell extract is incapable of detectable transcription from these promoters, successive purification by column chromatography allows the preparation of two fractions which contain all factors necessary for transcription from the 19S promoter. In contrast, transcription from the 35S promoter leads to the accumulation of short RNAs. This accumulation can only be partially alleviated by modifying the conditions of transcription.

Factor substitution in a human HSP70 gene promoter: TATA-dependent and TATA-independent interactions

To investigate interactions between transcription factors on mammalian promoters, we constructed a set of 24 variations of the human HSP70 gene promoter in which six upstream sequence motifs are paired in every possible combination with four TATA motifs. These promoters were analyzed for in vivo expression, and selected constructs were examined by in vitro template commitment studies. Activation transcription factor (ATF) and CP1 showed dramatically different interactions with the factor(s) bound to the TATA region. CP1 functioned in vivo regardless of the TATA motif that it was paired with and was not capable of sequestering the core promoter complex in a template commitment assay. ATF activity was dramatically altered by changing the TATA motif, and ATF was able to sequester the core promoter complex. These data suggest that CP1 and ATF function by distinct mechanisms that differ with respect to interaction with the factor(s) at the TATA box. Factor Sp1 also appeared to function by a TATA-independent mechanism. These data imply that the ability of a factor to function is determined not only by the intrinsic properties of the factor but also by promoter context.

Early events of RNA polymerase II transcription initiation

We have investigated the earliest stages of assembly of an RNA polymerase II transcription complex. General transcription factors from HeLa cells were partially purified and assayed using the adenovirus-2 major late promoter. Preincubation of either all the transcription factors (TF) with the DNA or only the subset consisting of TFIIA, TFIID, and DNA overcame the 15-20 min lag normally observed. The kinetics demonstrate that TFIIA first interacts with the template over a 5 min. period, and then TFIID interacts with the IIA:DNA complex over a 2 min. period. The remainder of the necessary transcription factors then interact with the IIA:IID:DNA complex. There are apparently interactions between IIA and IID, as a pre-incubation of these factors (without DNA) overcomes the lag period. Both IIA:DNA and IIA:DNA:IID interactions are temperature sensitive, resulting in slower kinetics at 0 degree C. Thus, the kinetics of transcription involve activation processes in addition to DNA binding.

Cell cycle-regulated gene expression in transgenic plant cells

A majority of histone genes are expressed in the S phase during the cell cycle. Using the gene expression system of transformed sunflower cells into which wheat histone H3 gene was introduced by the Ti-plasmid gene transfer technique, we determined three cis-acting control sequences (hexameric, octameric, and nonameric motifs) which seemed to confer the S-phase-specific transcription of wheat histone genes. Furthermore, as candidates for regulatory transcription factors, three nuclear DNA-binding proteins HBP-1a, HBP-1b, and HBP-2 that interact with the hexameric and nonameric motifs were identified. The structural analysis of the cDNA of HBP-1a revealed that a nuclear protein has the leucine-zipper structure and a DNA-binding motif. The hexameric motif in the H3 gene was also seen in cauliflower mosaic virus 35S (CaMV 35S) promoter and shown to function as a regulatory element of this promoter. The wheat HBP-1b can interact with the hexameric motif of the CaMV 35S promoter. Much attention has been paid to the significance of the hexameric sequences within the H3 and CaMV 35S promoters and the DNA-binding proteins HBP-1a and HBP-1b.

Factor substitution in a human HSP70 gene promoter: TATA-dependent and TATA-independent interactions

To investigate interactions between transcription factors on mammalian promoters, we constructed a set of 24 variations of the human HSP70 gene promoter in which six upstream sequence motifs are paired in every possible combination with four TATA motifs. These promoters were analyzed for in vivo expression, and selected constructs were examined by in vitro template commitment studies. Activation transcription factor (ATF) and CP1 showed dramatically different interactions with the factor(s) bound to the TATA region. CP1 functioned in vivo regardless of the TATA motif that it was paired with and was not capable of sequestering the core promoter complex in a template commitment assay. ATF activity was dramatically altered by changing the TATA motif, and ATF was able to sequester the core promoter complex. These data suggest that CP1 and ATF function by distinct mechanisms that differ with respect to interaction with the factor(s) at the TATA box. Factor Sp1 also appeared to function by a TATA-independent mechanism. These data imply that the ability of a factor to function is determined not only by the intrinsic properties of the factor but also by promoter context.

Identification of a yeast protein with properties similar to those of the immunoglobulin heavy-chain enhancer-binding protein NF-muE3

We demonstrate that Saccharomyces cerevisiae cells possess a 33-41-kilodalton protein with DNA-binding properties remarkably similar to those of the immunoglobulin enhancer-binding protein NF-muE3. We further show that the muE3-binding site functions as an upstream activating sequence in yeast cells, stimulating transcription from a truncated CYC1 promoter. These data suggest that the yeast protein, designated YEB-3, and NF-muE3 are functionally related and perhaps evolutionarily conserved.

Cloning of the gene encoding the yeast protein BTF1Y, which can substitute for the human TATA box-binding factor

An activity (designated BTF1Y) in extracts of Saccharomyces cerevisiae can substitute for the human TATA box-binding factor BTF1 in a reconstituted transcription system containing the adenovirus 2 major late promoter, RNA polymerase B (II), and the basic transcription factors BTF2, BTF3, and STF. We have purified BTF1Y to homogeneity, using as assays reconstitution of in vitro transcription and DNase I footprinting on the TATA element. Both activities copurified with a 27-kDa polypeptide as determined by SDS/PAGE. Gel filtration indicated a molecular mass of 28 +/- 5 kDa under nondenaturing conditions, suggesting that the native BTF1Y protein is a monomer. BTF1Y was enzymatically cleaved, several peptides were sequenced, and appropriate oligonucleotide probes were synthesized to clone the BTF1Y gene from a yeast genomic library. The BTF1Y gene contains a 720-base-pair open reading frame encoding a protein of 27,003 Da. The recombinant protein expressed in HeLa cells exhibited the same chromatographic characteristics and in vitro transcriptional activity as BTF1Y prepared from yeast extracts, confirming the identity of the gene. Gene-disruption experiments indicated that the yeast BTF1Y gene is a single-copy essential gene.

Characterization of the transcriptional potency of sub-elements of the UAS of the yeast PGK gene in a PGK mini-promoter

The upstream activator (UAS) of the yeast PGK gene comprises three different sequence elements. These are 1) a region of strong protein binding called the YFP, 2) three repeats of the motif CTTCC and 3) an essential activator core (AC) sequence that binds the protein RAP1. To assess the function of each of these elements in transcriptional activation we have inserted them individually and in various combinations into a PGK mini-promoter. This comprises only the transcription initiation elements from the PGK promoter and is inactive in the absence of activator sequences. None of the individual sequence elements was capable of activating the mini-promoter. However either the YFP or the CTTCC boxes in conjunction with the AC box resulted in efficient expression. Transcription levels were not however as high as when all three elements were inserted. These data suggest that the efficiency of PGK transcription depends upon the interactions between three different sequences. Furthermore while RAP1 per se is not a transcriptional activator it can associate promiscuously with other factors to create a functional transcription complex.

Initiation by yeast RNA polymerase II at the adenoviral major late promoter in vitro

Transcription of the yeast CYC1 promoter fused to a sequence lacking guanosine residues provided a rapid, sensitive assay of initiation by RNA polymerase II in yeast extracts. Initiation was enhanced by yeast and mammalian activator proteins. The adenoviral major late promoter fused to the G-minus sequence was transcribed in yeast extracts with an efficiency comparable to that observed in HeLa extracts, showing that promoters as well as transcription factors are functionally interchangeable across species. Initiation occurred at different sites, approximately 30 and 63 to 69 base pairs downstream of the TATA element of the adenoviral promoter in HeLa and yeast extracts, respectively, distances characteristic of initiation in the two systems in vivo. A component of the transcription system and not the promoter sequence determines the distance to the initiation site.

Identification of a yeast protein homologous in function to the mammalian general transcription factor, TFIIA

The yeast homolog of the mammalian RNA polymerase II general transcription factor TFIIA has been identified by complementation of a mammalian in vitro transcription system depleted for TFIIA. Like the mammalian factor, the yeast protein does not bind DNA, alters the size of the TFIID DNase I footprint at the adenovirus major late promoter, and forms specific TFIIA-TFIID-DNA complexes which are stable during electrophoresis in native acrylamide gels. The partially purified yeast factor was used to investigate its effect on the binding of TFIID to the major late promoter. Contrary to earlier models, we find that TFIIA does not significantly change the affinity or kinetics of TFIID binding, suggesting that it acts by altering the conformation of TFIID and/or by serving as a bridge between TFIID and the other general transcription factors.

Direct demonstration of termination signals for RNA polymerase II from the sea urchin H2A histone gene

Previous studies [1,2] suggested but did not prove that the sea urchin H2A histone gene possesses strong transcriptional termination signals close to, but separate from, the 3' processing signals. In this study we have demonstrated by two independent approaches that these sequences elicit authentic transcriptional termination. First we show by nuclear run off analysis that nascent transcription terminates in the immediate 3' flanking region of the H2A gene, in an A-rich region. Second we show that these termination signals prevent transcriptional read through when placed in the intron of a globin gene. The intronic position of the termination signal rules out any effect on steady state mRNA levels. We have therefore defined DNA sequences which act as a transcription terminator when placed in heterologous RNA polymerase II genes.

The evolutionary conservation of eukaryotic gene transcription

The basic components required for eukaryotic gene transcription have been highly conserved in evolution. Structural and functional homology has now been documented among promoters, promoter factors, regulatory proteins, and RNA polymerases from eukaryotes as diverse as yeast and mammals. The ability of these proteins and DNA sequences to function across phylogenetic boundaries demonstrates that common molecular mechanisms underlie gene control in all eukaryotic cells, and provides the basis for powerful new approaches to the study of eukaryotic gene transcription.

Structure and associated DNA-helicase activity of a general transcription initiation factor that binds to RNA polymerase II

RAP30/74 is a heteromeric general transcription initiation factor which binds to RNA polymerase II. Here we report that preparations of RAP30/74 contain an ATP-dependent DNA helicase whose probable function is to melt the DNA at transcriptional start sites. The sequence of the RAP30 subunit of RAP30/74 indicates that RAP30 may be distantly related to bacterial sigma factors.

Yeast TATA-box transcription factor gene

The first step in the transcription of most protein-encoding genes in eukaryotes is the binding of a transcription factor to the TATA-box promoter element. This TATA-box transcription factor was purified from extracts of the yeast Saccharomyces cerevisiae by using reconstitution of in vitro transcription reactions as an assay. The activity copurified with a protein whose sodium dodecyl sulfate/polyacrylamide gel mobility is 25 kDa. The sequence of the amino-terminal 21 residues of this protein was determined by sequential Edman degradation. A yeast genomic library was screened with mixed oligonucleotides encoding six residues of the protein sequence. The yeast TATA-box factor gene was cloned, and DNA sequencing revealed a 720-base-pair open reading frame encoding a 27,016-Da protein. The identity of the clone was confirmed by expressing the gene in Escherichia coli and detecting TATA-box factor DNA binding and transcriptional activities in extracts of the recombinant E. coli. The TATA-box factor gene was mapped to chromosome five of S. cerevisiae. RNA blot hybridization and nuclease S1 analysis indicated that the major TATA-box factor mRNA is 1.3 kilobases, including an unusually long 5' untranslated region of 188 +/- 5 nucleotides. Homology searches showed a region of distant similarity to the calcium-binding structures of calpains, a structure that has a conformation similar to the helix-turn-helix motif of DNA binding proteins.

Identification of a yeast protein with properties similar to those of the immunoglobulin heavy-chain enhancer-binding protein NF-muE3

We demonstrate that Saccharomyces cerevisiae cells possess a 33-41-kilodalton protein with DNA-binding properties remarkably similar to those of the immunoglobulin enhancer-binding protein NF-muE3. We further show that the muE3-binding site functions as an upstream activating sequence in yeast cells, stimulating transcription from a truncated CYC1 promoter. These data suggest that the yeast protein, designated YEB-3, and NF-muE3 are functionally related and perhaps evolutionarily conserved.

Cloning and structure of a yeast gene encoding a general transcription initiation factor TFIID that binds to the TATA box

The TATA sequence-binding factor TFIID plays a central role both in promoter activation by RNA polymerase II and other common initiation factors, and in promoter regulation by gene-specific factors. The sequence of yeast TFIID, which seems to be encoded by a single gene, contains interesting structural motifs that are possibly involved in these functions, and is similar to sequences of bacterial sigma factors.

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

The DNA binding properties of the yeast TATA element-binding protein TFIID were investigated. The affinity (apparent equilibrium dissociation constant) of TFIID for the adenovirus major late promoter consensus TATA element is 2 x 10(-9) M, a value similar to the affinity of gene-specific regulatory proteins for their binding sites. TFIID binding is highly specific and recognizes nonspecific sites with approximately 10(5)-fold lower affinity. Despite this specificity, TFIID also binds with high affinity to several TATA elements that do not match the consensus TATA sequences (TATAAA and TATATA): the yeast LEU2 TATA (TATTATTTA), the simian virus 40 TATA (CTTATTTAT), and the yeast CYC1 -10 TATA (TTATACATT) all bound TFIID. Furthermore, TFIID was active in promoting transcription in vitro from the nonconsensus TATA elements. Thus, contrary to previous suggestions, the existence of nonconsensus TATA elements does not itself indicate the existence of multiple TATA-binding factors.

Resolution and partial characterization of factors required for in vitro transcription by mammalian RNA polymerase II

Multiple protein factors from HeLa cells are necessary for the accurate initiation of transcription on minimal promoters in vitro. We have partially purified these factors by chromatographic methods. In addition to RNA polymerase II, six factors A-F (FA, FB, FC, FD, FE, and FF) necessary for initiation at the beta-globin promoter start site in vitro have been identified. Certain of these (FA, FC, and FE) have been purified to near homogeneity. The present purification scheme yields sufficient amounts of purified material for the more detailed characterization and cloning of the genes for these activities. Among these factors, FD and FF were required with template DNA at an early step of formation of the initiation complex, whereas FB, FA together with FC, and FE were effective when added at successively later stages in the process of complex formation.

Transcription of the alpha A-globin gene of the duck. Development of a homologous in vitro system and identification of trans-acting factors

A homologous in vitro transcription system was developed in which the alpha A-globin gene of the duck was faithfully transcribed. Whole-cell extracts from duck erythrocytes were separated into fractions A, B, C and D by consecutive elution from phosphocellulose columns and were individually reconstituted in run-off transcription assays. Fractions A, C and D were required to achieve faithful initiation on the alpha A-globin gene. The latter fractions were mutually interchangeable with comparable fractions from HeLa cells. A fourth fraction, B, was not required but enhanced basal transcription when reconstituted with fractions A, C and D or a very low amount of HeLa whole-cell extract which by itself did not yield a detectable signal. Fraction B from duck erythrocytes was further purified by chromatography on DEAE-Sephadex and was shown to contain two trans-acting factors. One of these differentially acts on the alpha A-globin gene of the duck. The other component from duck erythrocytes surprisingly resembles the upstream stimulatory factor, previously isolated from HeLa cells. This latter protein binds to and trans-activates the adenovirus 2 major late promoter, but is not involved in the transcription of the alpha A-globin gene.

Purification of a yeast TATA box-binding protein that exhibits human transcription factor IID activity

By a series of conventional chromatographic procedures we have purified from whole-cell extracts of Saccharomyces cerevisiae yeast transcription factor IID (TFIID), which functionally substitutes for human TFIID in a complementation assay comprised of the adenovirus type 2 major late promoter and HeLa cell-derived RNA polymerase II, transcription factors IIA, IIB, and IIE. Similar to its human counterpart, yeast TFIID also exhibited specific binding to the adenovirus type 2 major late promoter TATA element, as shown by both DNase I footprinting and gel mobility shift assays. NaDodSO4/PAGE analyses showed that a 27-kDa polypeptide coeluted with TFIID complementing activity through each chromatographic step. In agreement with this result and also suggesting that the native protein is a monomer, gel-filtration experiments indicated a molecular mass of 28 kDa for TFIID under nondenaturing conditions. That the 27-kDa polypeptide represented TFIID was further demonstrated by the ability of an HPLC-purified protein to bind specifically after renaturation to the adenovirus type 2 major late promoter TATA sequence.

Mutational analysis of a yeast transcriptional terminator

We have isolated and mutagenized a DNA fragment from Saccharomyces cerevisiae that specifies mRNA 3' end formation for the convergently transcribed CYC1 and UTR1 genes. An in vivo plasmid supercoiling assay previously showed that this fragment is a transcriptional terminator, and "run-on" assays shown here are consistent with this interpretation. The poly(A) sites in the mRNAs formed by the fragment are the same whether the fragment resides at the native location or at a heterologous location. No single linker substitution abolishes the fragment's activity, whereas certain large, nonoverlapping deletions have strong, deleterious effects. Therefore, the yeast terminator behaves more like rho-dependent bacterial terminators than terminators of higher eukaryotes. That a number of deletions or substitutions have different effects in the two orientations suggests that the fragment contains the sequences of two, unidirectional terminator elements.

Unusual C-terminal domain of the largest subunit of RNA polymerase II of Crithidia fasciculata

The C-terminal domain of the largest subunit of RNA polymerase II in higher eukaryotes is present in the protozoan parasite Trypanosoma brucei in a strongly modified form. To determine whether this is a general feature of the Kinetoplastida and to determine the role of this domain in RNA polymerase II transcription, we have analysed the C-terminal domain of the distantly related species Crithidia fasciculata. No positional identity of amino acid residues between the C-termini of C. fasciculata and T. brucei can be found. Moreover, both domains lack the heptapeptide repeat structure present in higher eukaryotes. The two domains are, however, very similar in amino acid composition, being rich in acidic residues as well as serine and tryosine. The latter observation is compatible with the concept that in vivo phosphorylation of the C-terminus activates RNA polymerase II.

Stability of transcription complexes on class II genes

Commitment of a TATA box-driven class II gene to transcription requires binding of only one transcription factor, TFIID. Additional factors (TFIIB, TFIIE, and RNA polymerase II) do not remain associated with the TFIID-promoter complex during the course of transcription. This indicates that there are two intermediates along the transcription reaction pathway which may be potential targets for the regulation of gene expression.

Mutations in RNA polymerase II enhance or suppress mutations in GAL4

The activation domains of eukaryotic DNA-binding transcription factors, such as GAL4, may regulate transcription by contacting RNA polymerase II. One potential site on RNA polymerase II for such interactions is the C-terminal tandemly repeated heptapeptide domain in the largest subunit (RPO21). We have changed the number of heptapeptide repeats in this yeast RPO21 C-terminal domain and have expressed these mutant RNA polymerase II polypeptides in yeast cells containing either wild-type or defective GAL4 proteins. Although the number of RPO21 heptapeptide repeats had no effect on the activity of wild-type GAL4, changing the length of the C-terminal domain modified the ability of mutant GAL4 proteins to activate transcription. Shorter or longer RPO21 C-terminal domains enhanced or partially suppressed, respectively, the effects of deletions in the transcriptional-activation domains of GAL4. The same RPO21 mutations also affected transcriptional activation by a GAL4-GCN4 chimera. These data suggest that the activation domains of DNA-binding transcription factors could interact, either directly or indirectly, with the heptapeptide repeats of RNA polymerase II.

Functional relationship among TATA sequences, gene induction and transcription initiation in the beta-galactosidase, LAC4, gene from Kluyveromyces lactis

In the 5' non-coding region of the beta-galactosidase, LAC4, gene of Kluyveromyces lactis, three TATA-like sequences are present at -230, -170 and -142 from the ATG translation start site. By means of deletion mutations in the TATA region, at least two of these TATA sequences, those at -230 and -142, were shown to be required for normal gene expression. Evidence is presented for a functional hierarchy and cooperation between these TATA sequences. The deletion or a change in the position of the TATA sequences affects both beta-galactosidase induction and the location of RNA initiation sites. The TATA sequence at -230 alone is sufficient for correct gene induction when it is moved to a position 41 bp from the major RNA initiation sites located around -110; the -142 TATA alone contributes only partly to gene induction. We suggest a functional distinction between these two related regulatory sequences. This functional distinction might be established by sequence differences and/or targets of unlike specific DNA binding protein(s). A conformational analysis of the LAC4 promoter showed that under torsional stress the functional elements UAS, TATA boxes RNA initiation sites and ATG can be detected as P1-sensitive sites. Possible functions of DNA structural alterations on gene expression are discussed.

Mammalian cAMP-responsive element can activate transcription in yeast and binds a yeast factor(s) that resembles the mammalian transcription factor ANF

The human ATF and AP1 transcription factors bind to highly related DNA sequences. Their consensus binding sites differ by a single nucleotide, but this single change is crucial in determining factor binding specificity. We have previously identified an AP1 (yAP1) binding activity in yeast. In this report we identify a yeast ATF (yATF) binding activity whose specificity can be distinguished from that of yAP1 by the same crucial nucleotide that distinguishes binding of human ATF and AP1. The ATF binding site can act as an efficient upstream activating sequence in vivo, suggesting that yATF is a transcriptional activator. The yATF DNA-binding complex is phosphorylated and the binding activity of partially purified yATF can be enhanced in vitro by the addition of protein kinase A, indicating that the phosphorylation state of yATF may be important in determining its ability to bind DNA.

Preproenkephalin DNA-binding proteins in the rat: 5' flanking region

Various extracellular signals (i.e. transmitters, hormones, growth factors, etc.), together with their respective second-messenger pathways, regulate transmitter biosynthesis and neuronal function by altering gene expression. In this study we validated a protocol for isolating rat striatum and adrenal medullary nuclei for the purpose of extracting, identifying, and characterizing, nuclear regulatory factors which may serve a functional role in signal-transduction processes. Through gel retardation studies using a 299 base pair (bp) XmnI-SacI 32P-labeled probe (derived from the 5' untranslated region of the rat preproenkephalin gene), we show that different patterns of retained bands result from nuclear extracts derived from rat adrenal medulla and striatum (as well as from other tissue). These tissue differences may have biological significance since rat adrenal medullae have low basal enkephalin levels while the striatum has high levels of this peptide and its respective mRNA. Additionally, certain retained bands were common to both cytosolic and nuclear compartments, suggesting binding factors may be located in either cell space. An initial biochemical characterization of these factors was also undertaken. Generally, salt levels of 100 mM or more reduced factor binding while 10-50 mM sodium ion levels showed preferentially enhanced bands. Binding activity appeared optimal at pH 6.8. As all retained bands were abrogated by proteinase K treatment, these factors appear to have a significant protein component. Finally, of particular interest is that this 299 bp region contains many sequences showing over 80% sequence identity with several previously characterized transcriptional control elements (i.e. cAMP and phorbol ester inducible enhancers, GCN4, AP1, Sp1, CCAAT binding factor, ATF, and AP2). If binding is confirmed (footprint analysis) and function validated (transfection studies), the evolutionary significance of the apparent presence of gene regulatory sequences and functional element divergence of the DNA region between different species can be evaluated.

Yeast YAP1 encodes a novel form of the jun family of transcriptional activator proteins

The jun family of transcriptional activators includes mammalian AP-1 as well as the yeast regulatory protein GCN4. Recently, an additional transcriptional activator has been found in yeast that recognizes the TGACTCA sequence element common in GCN4/AP-1 sites. This factor was designated yAP-1. The structural gene for yAP-1 has now been isolated and characterized. The deduced amino acid sequence predicts a protein of 650 residues, considerably larger than GCN4 or c-Jun. The amino terminus of yAP-1 is homologous to the carboxy-terminal DNA-binding domains of GCN4 and c-Jun. Disruption of the YAP1 gene demonstrates this gene is not essential but is required for AP-1 recognition element-dependent transcriptional activation. DNA-affinity blots of proteins from YAP1 cells suggest the presence of additional TGACTCA-binding proteins other than GCN4 and yAP-1. Furthermore, expression of at least one of these related DNA-binding proteins appears to be under control of yAP-1.