Showing papers on "Upstream activating sequence published in 1986"

Upstream regions of the human cardiac actin gene that modulate its transcription in muscle cells: presence of an evolutionarily conserved repeated motif

Abstract: Transfection into cultured cell lines was used to investigate the transcriptional regulation of the human cardiac actin gene. We first demonstrated that in both human heart and human skeletal muscle, cardiac actin mRNAs initiate at the identical site and contain the same first exon, which is separated from the first coding exon by an intron of 700 base pairs. A region of 485 base pairs upstream from the transcription initiation site of the human cardiac actin gene directs high-level transient expression of the bacterial chloramphenicol acetyltransferase gene in differentiated myotubes of the mouse C2C12 muscle cell line, but not in mouse L fibroblast or rat PC-G2 pheochromocytoma cells. Deletion analysis of this region showed that at least two physically separated sequence elements are involved, a distal one starting between -443 and -395 and a proximal one starting between -177 and -118, and suggested that these sequences interact with positively acting transcriptional factors in muscle cells. When these two sequence elements are inserted separately upstream of a heterologous (simian virus 40) promoter, they do not affect transcription but do give a small (four- to fivefold) stimulation when tested together. Overall, these regulatory regions upstream of the cap site of the human cardiac actin gene show remarkably high sequence conservation with the equivalent regions of the mouse and chick genes. Furthermore, there is an evolutionarily conserved repeated motif that may be important in the transcriptional regulation of actin and other contractile protein genes.

Removal of positioned nucleosomes from the yeast PHO5 promoter upon PHO5 induction releases additional upstream activating DNA elements.

Abstract: The chromatin fine structure in the promoter region of PHO5, the structural gene for a strongly regulated acid phosphatase in yeast, was analyzed An upstream activating sequence 367 bp away from the start of the coding sequence that is essential for gene induction was found to reside in the center of a hypersensitive region under conditions of PHO5 repression Under these conditions three related elements at positions -469, -245 and -185 are contained within precisely positioned nucleosomes located on both sides of the hypersensitive region Upon PHO5 induction the chromatin structure of the promoter undergoes a defined transition, in the course of which two nucleosomes upstream and two nucleosomes downstream of the hypersensitive site are selectively removed In this way approximately 600 bp upstream of the PHO5 coding sequence become highly accessible and all four elements are free to interact with putative regulatory proteins These findings suggest a mechanism by which the chromatin structure participates in the functioning of a regulated promoter

Transcriptional "silencer" element in rat repetitive sequences associated with the rat insulin 1 gene locus.

Abstract: The enhancer elements from either simian virus 40 or murine sarcoma virus activate the expression of a transfected rat insulin 1 (rI1) gene when placed within 2.0 kilobases or less of the rI1 gene cap site. Inclusion of 4.0 kilobases of upstream rI1 sequence, however, results in a substantial reduction in the enhancer-dependent insulin gene expression. These observations suggested that a negative transcriptional regulatory element was present between 2.0 and 4.0 kilobases of the rI1 sequence. To test this notion, we employed a heterologous enhancer-dependent transcription assay in which the simian virus 40 72-base-pair repeat is linked to a human beta-globin gene. Addition of the upstream rI1 element to this system decreased the level of enhancer-dependent beta-globin transcription by a factor of 5 to 15. This rI1 "silencer" element functions in a manner relatively independent of position and orientation and requires a cis-dependent relationship to the transcription unit on which it acts. Thus, the silencer sequence seems to have a number of the characteristics of enhancer elements, and we suggest that it may function by the converse of the enhancer mechanism. The rI1 silencer sequence was identified as a member of a long interspersed rat repetitive family. Thus, a potential role for certain repetitive sequences interspersed throughout the eukaryotic genome may be to regulate gene expression by retaining transcriptional activity within defined domains.

Novel promoter upstream of the human c-myc gene and regulation of c-myc expression in B-cell lymphomas.

Abstract: A new promoter of the human c-myc gene called P0, with multiple RNA start sites, was mapped over 500 bases upstream of the two previously identified promoters, P1 and P2. Sequencing full-length cDNA clones of P0 RNAs revealed two open reading frames upstream of that for the P64c-myc protein. P0 RNA is located on polyribosomes and released by puromycin, indicating that it functions as an mRNA. In vitro translation of RNA synthesized from the cloned cDNAs predicts that P0 transcripts are translated into a novel 12.5-kilodalton protein corresponding to the first open reading frame. The regulation of P0 RNA was studied in the B-cell lymphoma cell line Manca, in which only the translocated c-myc allele lacking exon 1 was thought to be active. However, we found that P0 transcription and the DNase I-hypersensitive site associated with this promoter persist on the untranslocated allele, even though P1/P2 transcription as measured by a nuclear runoff assay was repressed. These results suggest that allelic exclusion of c-myc expression in this B-cell lymphoma is caused by a repression of transcription which is specific to the P1/P2 promoters. We previously reported a block to elongation of transcription near the 3' end of exon 1 in the wild-type c-myc gene, which results in an excess of exon 1 over exon 2 transcription (5a). In contrast, we found that in the Daudi B-cell lymphoma, which retains exon 1 in the active allele, equimolar transcription of exons 1 and 2 occurs. This result suggests a model for the activation of c-myc in B-cell lymphomas.

Transcriptional control of the mouse prealbumin (transthyretin) gene: both promoter sequences and a distinct enhancer are cell specific.

Abstract: The mouse genomic clone for the prealbumin (transthyretin) gene was cloned, and its upstream regulatory regions were analyzed. The 200 nucleotides 5' to the cap site when placed within a recombinant plasmid were sufficient to direct transient expression in HepG2 (human hepatoma) cells, but this DNA region did not support expression in HeLa cells. The sequence of the 200-nucleotide region is highly conserved between mouse and human DNA and can be considered a cell-specific promoter. Deletions of this promoter region identified a crucial element for cell-specific expression between 151 and 110 nucleotides 5' to the RNA start site. A region situated at about 1.6 to 2.15 kilobases upstream of the RNA start site was found to stimulate expression 10-fold in HepG2 cells but not in HeLa cells. This far upstream element was invertible and increased expression from the beta-globin promoter in HepG2 cells. Unlike the simian virus 40 enhancer, the prealbumin enhancer would not stimulate beta-globin synthesis in HeLa cells, and even the simian virus 40 enhancer did not stimulate the prealbumin promoter in HeLa cells. Thus, we identified in the prealbumin gene two DNA elements that respond in a cell-specific manner: a proximal promoter including a crucial sequence between -108 and -151 nucleotides and a distant enhancer element located between 1.6 and 2.15 kilobases upstream.

An RNA polymerase I enhancer in Saccharomyces cerevisiae.

Abstract: By the use of an artificial gene coding for rRNA (rDNA gene), we found that transcription of the major precursor rRNA in Saccharomyces cerevisiae cells is stimulated 15-fold by a positive control element located 2 kilobases upstream of the transcription initiation site. Analysis of in vitro runon transcripts suggests that this promoter element increases the frequency of initiation by RNA polymerase I molecules. A 190-base-pair fragment encompassing the promoter element can stimulate transcription on a centromere plasmid in either orientation, upstream or downstream of the transcription initiation site, suggesting that it is an enhancer element. Integration of artificial rDNA genes into a nonribosomal locus in the genome demonstrates that the rDNA enhancer functions either 5' or 3' to an rRNA transcription unit, suggesting it may operate in both directions within the rDNA tandem array. This is the first observation in S. cerevisiae of the stimulation of transcription by an element placed downstream. Finally, enhancer activity is dependent upon sequences that lie at both boundaries of the 190-base-pair fragment. In particular, a 5-base-pair deletion at the extreme 3' boundary of the 190-base-pair fragment greatly reduces the activation of transcription and implicates a set of inverted repeats.

Efficient expression of the Saccharomyces cerevisiae PGK gene depends on an upstream activation sequence but does not require TATA sequences.

Abstract: The Saccharomyces cerevisiae PGK (phosphoglycerate kinase) gene encodes one of the most abundant mRNA and protein species in the cell. To identify the promoter sequences required for the efficient expression of PGK, we undertook a detailed internal deletion analysis of the 5' noncoding region of the gene. Our analysis revealed that PGK has an upstream activation sequence (UASPGK) located between 402 and 479 nucleotides upstream from the initiating ATG sequence which is required for full transcriptional activity. Deletion of this sequence caused a marked reduction in the levels of PGK transcription. We showed that PGK has no requirement for TATA sequences; deletion of one or both potential TATA sequences had no effect on either the levels of PGK expression or the accuracy of transcription initiation. We also showed that the UASPGK functions as efficiently when in the inverted orientation and that it can enhance transcription when placed upstream of a TRP1-IFN fusion gene comprising the promoter of TRP1 fused to the coding region of human interferon alpha-2.

A GAL family of upstream activating sequences in yeast: roles in both induction and repression of transcription.

Abstract: Binding sites for the GAL4-positive regulatory protein have been identified upstream of six galactose-inducible genes of Saccharomyces cerevisiae on the basis of (i) protection in DNAse I footprints, (ii) loss of protection when excess GAL4-binding oligonucleotide is added and (iii) homology with a 23-bp dyad-symmetric consensus sequence. Many of the binding sites have been shown to function as upstream activating sequences. The number of binding sites upstream of the various genes ranges from one to four, but a feature is conserved: in cases of multiple sites there is a pair with highest binding affinity located at dyad--dyad distances of 82--87 bp. We suggest that a pair of sites facilitates repression by the GAL80-negative regulatory protein, on the basis of (i) a correlation of a pair of sites (or only one) with full (or only partial) repression and (ii) the introduction of a second site abolishing transcription occurring with one.

Tripartite upstream promoter element essential for expression of Saccharomyces cerevisiae ribosomal protein genes.

Abstract: To initiate a genetic analysis of yeast ribosomal protein gene promoters, we have constructed a gene fusion between the yeast ribosomal protein gene RP39A and the Escherichia coli lacZ gene. This gene fusion contains approximately 1,030 nucleotides of the 5' flanking region and the first 49 1/3 codons of RP39A fused in frame to a large 3' end fragment of lacZ. Whether it is introduced into yeast cells on a moderately high-copy-number plasmid, or integrated into the yeast genome at the RP39A locus, this RP39A-lacZ gene directs the synthesis of a hybrid transcript which encodes beta-galactosidase activity. Deletions in the 5' flanking region of RP39A-lacZ were constructed by linker insertion and BAL 31 mutagenesis. The expression of the mutant genes in yeast cells was assayed by measuring RP39A-lacZ mRNA and beta-galactosidase levels. By these means we have shown that the sequences between nucleotides -256 and -170 upstream of RP39A are essential for expression of this gene. Three sequence motifs, HOMOL1, RPG, and a T-rich region, which were found in that order 5'----3' upstream of most yeast ribosomal protein genes, were present within this interval. We found that substitution of the CYC1-lacZ upstream activation site with the fragment from nucleotides -298 to -172 upstream of RP39A, containing the HOMOL1-RPG-T-rich motif in that 5'----3' orientation, fully restored expression of the CYC1-lacZ gene. The essentially of HOMOL1, the RPG sequence, and the T-rich region for wild-type levels of expression of RP39A, the conserved location and order of these sequence motifs in yeast ribosomal protein genes, and the ability of a DNA fragment carrying these three sequence elements to substitute for the upstream activation site regions of CYC1 indicate that these three oligonucleotides may be essential to the transcription of yeast ribosomal protein genes.

Two distinct promoter elements in the human rRNA gene identified by linker scanning mutagenesis.

Abstract: A cell-free RNA polymerase I transcription system was used to evaluate the transcription efficiency of 21 linker scanning mutations that span the human rRNA gene promoter. Our analysis revealed the presence of two major control elements, designated the core and upstream elements, that affect the level of transcription initiation. The core element extends from -45 to +18 relative to the RNA start site, and transcription is severely affected (up to 100-fold) by linker scanning mutations in this region. Linker scanning and deletion mutations in the upstream element, located between nucleotides -156 and -107, cause a three- to fivefold reduction in transcription. Under certain reaction conditions, such as the presence of a high ratio of protein to template or supplementation of the reaction with partially purified protein fractions, sequences upstream of the core element can have an even greater effect (20- to 50-fold) on RNA polymerase I transcription. Primer extension analysis showed that RNA synthesized from all of these mutant templates is initiated at the correct in vivo start site. To examine the functional relationship between the core and the upstream region, mutant promoters were constructed that alter the orientation, distance, or multiplicity of these control elements relative to each other. The upstream control element appears to function in only one orientation, and its position relative to the core is constrained within a fairly narrow region. Moreover, multiple core elements in close proximity to each other have an inhibitory effect on transcription.

Regulatory DNA elements localized remotely upstream from the drug-metabolizing cytochrome P-450c gene.

Abstract: We have investigated regulatory DNA elements in the expression of the drug metabolizing P-450c gene of rats. After combining the 5' flanking and upstream untranslated regions of the isolated P-450c gene with structural gene for chloramphenicol acetyltransferase (CAT), the fusion genes were transfected into cultured cells (Hepa-1 and L cells) for the assay of transient expression of CAT activity. CAT activity was expressed inducibly in response to 3-methylcholanthrene only in Hepa-1 cells. At least three regions containing regulatory DNA elements were indentified; one, which is present in the sequence from -44b to -0.2kb immediately upstream of the TATA box, functions in the basal level of transcription, and the other two which were located in the sequence from -0.8kb to -1.0kb and from -1.0kb to -6.3kb, enhance in combination, transcription in response to inducers in a manner independent of their orientation.

Purification of a factor specific for the upstream element of the adenovirus-2 major late promoter.

Abstract: Stimulation of in vitro transcription by the upstream element (UE) of the adenovirus-2 major late promoter (Ad2MLP) involves a specific trans-acting factor present in a HeLa whole-cell extract. By following its transcriptional stimulatory activity and its DNase I footprint on the Ad2MLP-UE, we have purified this factor to greater than 10% purity and separated it from RNA polymerase B and the general transcription factors required for transcription from the Ad2MLP.

Conserved sequence elements upstream of the gene encoding yeast ribosomal protein L25 are involved in transcription activation.

Abstract: Previous studies have revealed the occurrence of two closely linked conserved sequence elements, designated as HOMOL 1 and RPG box, in front of most yeast ribosomal protein genes examined. To investigate whether these conserved nucleotide elements play a role in the regulation of ribosomal protein gene expression, we performed deletion analysis of the DNA region upstream of the gene encoding ribosomal protein L25. To that end we constructed a hybrid gene consisting of the pertinent 5'-flanking sequence and the Escherichia coli galK marker gene. The effects on the transcription of this fusion gene of Bal31-generated deletions were measured by Northern analysis of RNA isolated from the respective transformed yeast cells. The results demonstrate that removal of one box has a detrimental effect on the level of transcription, whereas after the deletion of both boxes hardly any transcription can be observed. Subsequently we inserted synthetic oligonucleotides in the upstream region of an L25 gene from which the original boxes had been removed. Expression of the inactivated hybrid gene turned out to be restored even by insertion of one RPG element. Moreover, the RPG box functions in both orientations, though not with equal efficiency.

A subpopulation of spinach chloroplast tRNA genes does not require upstream promoter elements for transcription

Abstract: We have identified a class of spinach plastid tRNA genes which do not require 5' upstream promoter elements for their expression in a chloroplast transcription system. The 5' DNA sequences flanking the trnR1 and trnS1 coding regions have little or no homology to previously characterized chloroplast promoter sequences. The deletion of the 5' DNA sequences from these genes to positions close to the start of the coding regions has little effect on their transcription in vitro. In addition, a synthetic DNA fragment homologous to the 5' region of trnS1 does not support the transcription of the promoter (-) trnM2 mutant 51 in a promoter/trnM2-51 fusion assay. In a dicistronic construct the wild type trnS1 gene does not support transcription of trnS1 transcription occurs immediately following the 3' end of the coding region. Both trnS1 and trnR1 compete with trnM2 for the same chloroplast RNA polymerase and/or common transcription factors.

Duplicate upstream activating sequences in the promoter region of the Saccharomyces cerevisiae GAL7 gene.

Abstract: We constructed a series of deletions in the 5' noncoding region of the Saccharomyces cerevisiae GAL7 gene, fused them to the Escherichia coli gene lacZ, and introduced them into yeasts by using a multicopy vector. We then studied the effect of the deletions on beta-galactosidase synthesis directed by the gene fusions in media with various carbon sources. This analysis identified a TATA box and two upstream activating sequences as necessary elements for galactose-controlled GAL7 transcription. Two upstream activating sequences exhibiting 71% homology with each other were located 255 and 168 base pairs, respectively, upstream of the GAL7 transcription start point. Each sequence consists of 21 base pairs, displaying an approximate rotational symmetry with a core consensus sequence of GAA--AGCTGCTTC--CGCG. At least one of the two sequences is required for galactose induction and also for glucose repression of the GAL7'-lac'Z gene. Analysis with host regulatory mutants delta gal14 and delta gal180 suggests that these sequences are the site at which the GAL4 product exerts its action to activate the GAL7 gene. We also observed that a deletion lacking both upstream activation sequences allowed the gene fusion to be expressed in the absence of galactose at about 10% of the fully induced level of the intact fusion. This constitutive expression depended on the presence of the TATA box of GAL7 in cis but not on a functional GAL4 gene. The level of the uncontrolled expression was decreased by increasing the distance between the TATA box and the pBR322 sequence in the vector plasmid.

Precise assignment of the light-strand promoter of mouse mitochondrial DNA: a functional promoter consists of multiple upstream domains.

Abstract: Using deletion mutagenesis we localized the promoter for the light strand of mouse mitochondrial DNA to a 97-base-pair region, from -88 to +9 nucleotides of the transcriptional initiation site. Within this region the light-strand promoter could be dissected into at least three different functional domains. The specificity region, a maximum of 19 base pairs between -10 and +9 of the transcriptional initiation site, was essential and sufficient for accurate transcriptional initiation. A second region, extending to -29 nucleotides from the initiation site, facilitated the formation of a preinitiation complex between the template DNA and factor(s) present in the mitochondrial RNA polymerase fraction and was required for efficient transcription. A third, ill-defined upstream region, which extended up to -88 nucleotides from the initiation site, appeared to influence template transcriptional efficiencies in competition assays. Without the specificity domain, the upstream regions were incapable of supporting any transcription. The presence of multiple upstream domains was confirmed by disrupting nucleotide sequences in the upstream region by using linker insertion and linker replacement techniques.

Sequences upstream of the STE6 gene required for its expression and regulation by the mating type locus in Saccharomyces cerevisiae.

Abstract: The STE6 gene of Saccharomyces cerevisiae is an a-specific gene; it is repressed in alpha cells by the alpha 2 product of the mating type locus. To study the role of sequences upstream of STE6 in its regulation and expression, we have determined the DNA sequence of the promoter region, identified the start sites for the STE6 transcript, and identified sequences governing its transcription. Deletions that remove DNA upstream of the STE6 gene were produced and assayed for effects on regulation and expression. The deletions defined two intervals upstream of the STE6 transcription initiation sites. One contains all or part of a negative element; the other contains all or part of a positive element. The negative element is required for repression of STE6 by alpha 2: deletions lacking this element express STE6 constitutively. Such deletions remove a 31-base-pair site, located 135 base pairs upstream of the first transcript start site, that is highly homologous to sites present in the upstream regions of four other genes repressed by alpha 2. These sites are presumably responsible for repression of the a-specific genes by alpha 2. The positive element (a putative upstream activation site) is required for expression of STE6. The deletions define the left boundary of the proposed upstream activation site. Sequence homologies between STE6 and other a-specific genes are found in this region and may mediate activation of this set of genes.

Short repeated elements in the upstream regulatory region of the SUC2 gene of Saccharomyces cerevisiae.

Abstract: Expression of secreted invertase from the SUC2 gene is regulated by carbon catabolite repression. Previously, an upstream regulatory region that is required for derepression of secreted invertase was identified and shown to confer glucose-repressible expression to the heterologous promoter of a LEU2-lacZ fusion. In this paper we show that tandem copies of a 32-base pair (bp) sequence from the upstream regulatory region activate expression of the same LEU2-lacZ fusion. The level of expression increased with the number of copies of the element, but was independent of their orientation; the expression from constructions containing four copies of the sequence was only twofold lower than that when the entire SUC2 upstream regulatory region was present. This activation was not significantly glucose repressible. The 32-bp sequence includes a 7-bp motif with the consensus sequence (A/C)(A/G)GAAAT that is repeated at five sites within the upstream regulatory region. Genetic evidence supporting the functional significance of this repeated motif was obtained by pseudoreversion of a SUC2 deletion mutant lacking part of the upstream region, including two copies of the 7-bp element. In three of five pseudorevertants, the mutations that restored high-level SUC2 expression altered one of the remaining copies of the 7-bp element.

Identification of the DNA sequences controlling the expression of the MAT alpha locus of yeast.

Abstract: We have excised a 28-base-pair DNA fragment from the MAT alpha intergenic region and tested its ability to direct diploid-specific transcriptional repression. This fragment (1643-1671, 5'-GCTTCCCAATGTAGAAAAGTACA-TCATA-3') lies within a region required for the normal diploid-specific repression of the MAT alpha transcripts. First, the fragment was inserted into a 53-base-pair MAT alpha deletion that expresses alpha 1 and alpha 2 constitutively. Insertion of the fragment restores proper diploid regulation to the MAT alpha transcripts: alpha 1 mRNA is strongly repressed and alpha 2 mRNA is reduced by a factor of approximately equal to 10 from its haploid level. The fragment works equally well in either orientation, and two copies of the fragment do not lead to stronger repression than a single copy. We also inserted the fragment at three sites upstream of the CYC1-lacZ fusion gene. Insertions placing the regulatory fragment between the CYC1 upstream activator sequence (UAS) and the coding region make beta-galactosidase efficiently in alpha haploids but produce 1/40th the enzyme in a/alpha diploids. This diploid-specific repression requires functional MATa-1 gene product. Insertion of the MAT fragment on the opposite side of the UAS (37 base pairs upstream of the UAS) also caused diploid repression of the fusion gene, but only by a factor of 7. When the regulatory fragment is inserted at a large distance on the far side of the UAS (375 base pairs), it has little if any effect on beta-galactosidase expression. We postulate that this sequence is the operator recognized by the diploid-specific repressor.

An upstream signal is required for in vitro transcription of Neurospora 5S RNA genes.

Abstract: The DNA sequences upstream of the 5S RNA genes inNeurospora crassa are largely different from one another, but share a short consensus sequence located in the segment 29 to 26 nucleotides preceding the transcribed region. Differences among flanking sequences do not appear to affect transcription. Deletion analysis indicates, however, that a DNA segment including the conserved “TATA box” is required for in vitro transcription of Neurospora 5S RNA genes.

The core promoter of mouse rDNA consists of two functionally distinct domains

Abstract: We have determined the sequences constituting the minimal promoter of mouse rDNA. A very small region immediately upstream of the transcription start site (from -1 to -39) is sufficient to direct correct transcription initiation. Sequences immediately downstream of the transcription start site (+1 to +11) increase the efficiency of transcription initiation. Point mutations within the core promoter have been generated and assayed for their effects on template activity and on interaction with the pol I specific transcription factor TIF-IB. The core promoter element appears to consist of two functionally different domains. The distal sequence motif from position -22 to -16 is recognized by factor TIF-IB. Mutations within this region lead to similar changes of both template activity and binding of TIF-IB. Two point mutations within the proximal sequence motif from -15 to -1 do not affect TIF-IB binding although they severely impair transcription initiation. It is suggested, that this proximal region plays a role in the assembly of functional transcription initiation complexes rather than in the primary binding of TIF-IB.

Structure of RNA polymerase II promoters. Conformational alterations and template properties of circularized Saccharomyces cerevisiae GAL1-GAL10 divergent promoters.

Abstract: A DNA fragment encompassing the Saccharomyces cerevisiae GAL1--GAL10 divergent promoters (914 bp) has been circularized in vitro with T4 DNA ligase. We have defined a set of conditions that allows the production of a series of nine topoisomers covering a range from relaxed to highly negatively supercoiled DNA. Topoisomers were recovered in pure form from agarose gels and were analysed singly for the presence of sites sensitive to the single strand-specific endonuclease Pl. In this way, the occurrence of conformational alterations as a function of the linking deficiency of the closed DNA domain has been determined. Interestingly, sites of Pl hypersensitivity localize on the three sequences identified as relevant for the in vitro transcription of the GAL1 moiety of the divergent promoter: the upstream activator sequence (UAS), the TATA sequence, and the RNA initiation site (RIS). In vitro transcription with purified S. cerevisiae RNA polymerase II shows that activation of transcription parallels the appearance of conformational alterations on the UAS, the TATA and the RIS sequences.

Saccharomyces cerevisiae PHO5 promoter region: location and function of the upstream activation site.

Abstract: Saccharomyces cerevisiae repressible acid phosphatase (PHO5) is induced when inorganic phosphate in the culture medium is depleted. To study the mechanism of this regulation, we constructed various deletions in the 5'-flanking region of the PHO5 gene. Two elements were revealed by this analysis: an upstream activation site (UAS) and a downstream element, both playing parts in the expression of this gene. The UAS is located between -384 and -292 upstream of the initiation codon and activates expression of the gene when inorganic phosphate is depleted. It consists of two homologous regions (UAS I and UAS II) that contain CTGCACAAATG and an adenine-plus-thymine-rich sequence, either one of which suffices for the effect. The downstream element includes a putative TATA box at -100 from the ATG codon and is necessary for efficient transcription and expression of the normal-sized PHO5 transcript. The distance between the UAS and the downstream element can be altered without causing loss of expression efficiency, and the action of the UAS is not affected by its orientation. These results are consistent with a model wherein UAS acts as a site of activation for transcription by interaction with a protein factor(s) that becomes active when inorganic phosphate is depleted from the culture medium.

Characterization of the promoter of the large ribosomal RNA gene in yeast mitochondria and separation of mitochondrial RNA polymerase into two different functional components.

Abstract: We have characterized a DNA sequence that functions in recognition of the promoter of the mitochondrial large rRNA gene by the yeast mtRNA polymerase. Promoter-containing DNA fragments were mutagenized and used as templates to study initiation of transcription in vitro with a partially purified mtRNA polymerase preparation. Deletion mutants, in which increasing stretches of DNA were removed from regions flanking the promoter, define a short area essential for correct initiation of transcription. It virtually coincides with a highly conserved stretch of nine nucleotides that is found immediately upstream of all transcriptional start sites described thus far. Two different point mutations within this nonanucleotide sequence drastically reduce promoter function. Conversely a single point mutation that results in the formation of a nonanucleotide sequence 99 nucleotides upstream of the large rRNA gene leads to a new, efficient transcription initiation site. MtRNA polymerase can be resolved into two different components by chromatography on Blue Sepharose: one retaining the capacity to synthesize RNA, the other conferring the correct specificity of initiation to the catalytic component.

A DNA fragment containing the upstream activator sequence determines nucleosome positioning of the transcriptionally repressed PHO5 gene of Saccharomyces cerevisiae.

Abstract: The functional relationship of nucleosome positioning and gene expression is not known. Using high-copy plasmids, containing the yeast phosphate-repressible acid phosphatase gene (PHO5) and the TRP1/ARS1 vector system, I have determined the nucleosomal structure of the 5' region of the PHO5 gene and demonstrated that the nucleosomal positioning of this region is independent of orientation or position in the various plasmid constructions utilized. However, deletion of a 278-base pair BamHI-ClaI fragment from the 5'-flanking sequences of the PHO5 gene causes the nucleosome positioning to become dependent on orientation or position in the plasmids tested. Use of PHO5-CYC1-lACZ fusions have demonstrated that this DNA fragment contains the sequences responsible for the transcriptional regulation of the PHO5 gene in response to the level of phosphate in the growth media. The nucleosome positioning in the 5' region of PHO5 may be determined by an interaction with the sequences or machinery responsible for transcriptional regulation of the gene.

Regulatory sequences in the promoter of the Dictyostelium Actin 6 gene.

Abstract: The promoter region of the developmentally regulated Actin 6 gene of Dictyostelium has been dissected by a series of deletions. Functional analysis of the deletions in Dictyostelium transformants revealed two short regulatory sequences: a positive upstream element (PUE) between -599 and -572 which increases transcription by a factor of 10 but does not affect the developmental pattern of expression and an upstream activator sequence (UAS) between -249 and -215 which is essential for transcription and proper developmental regulation. The UAS partially coincides with a conserved sequence with dyad symmetry found upstream of several Dictyostelium actin genes (Romans and Firtel, 1985a).