Deletion mapping of the yeast Pol I promoter

The yeast alpha 2 protein can repress transcription by RNA polymerases I and II but not III

The alpha 2 protein of the yeast Saccharomyces cerevisiae normally represses a set of cell-type-specific genes (the a-specific genes) that are transcribed by RNA polymerase II. In this study, we determined whether alpha 2 can affect transcription by other RNA polymerases. We find that alpha 2 can repress transcription by RNA polymerase I but not by RNA polymerase III. Additional experiments indicate that alpha 2 represses RNA polymerase I transcription through the same pathway that it uses to repress RNA polymerase II transcription. These results implicate conserved components of the transcription machinery as mediators of alpha 2 repression and exclude several alternate models.

The yeast alpha 2 protein can repress transcription by RNA polymerases I and II but not III

The alpha 2 protein of the yeast Saccharomyces cerevisiae normally represses a set of cell-type-specific genes (the a-specific genes) that are transcribed by RNA polymerase II. In this study, we determined whether alpha 2 can affect transcription by other RNA polymerases. We find that alpha 2 can repress transcription by RNA polymerase I but not by RNA polymerase III. Additional experiments indicate that alpha 2 represses RNA polymerase I transcription through the same pathway that it uses to repress RNA polymerase II transcription. These results implicate conserved components of the transcription machinery as mediators of alpha 2 repression and exclude several alternate models.

The yeast RNA polymerase I promoter: ribosomal DNA sequences involved in transcription initiation and complex formation in vitro

Using an in vitro transcription system for Saccharomyces cerevisiae RNA polymerase I, we have analyzed Pol I promoter deletion mutants and mapped the boundaries of the promoter between positions -155 and +27. The 5'-boundary of the minimal core promoter capable of transcription initiation, however, was found to lie between -38 and -26. The 3'-deletion extending to -2 and -5 still allowed some transcription, suggesting that the positioning of Pol I is directed by upstream sequences. The results of in vitro analysis of linker scanning mutants (LSMs) combined with the deletion analysis showed that the promoter consists of three domains: two essential core domains (I: -28 to +8 and II: -76 to -51) and a transcription modulating upstream domain (III: -146 to -91). These results are in general agreement with those obtained in vivo (1). Using a template competition assay we also analyzed these mutant promoters for their ability to form a stable preinitiation complex. We found that the ability of 5'-deletion mutants to sequester an essential factor(s) correlates with their transcriptional activity. In contrast, several 3'-deletions and some LSMs in domain I and II decrease transcription activity greatly without significantly decreasing competition ability. The results indicate that the stimulatory function of domain III is achieved through its interaction with an essential transcription factor(s), although the other domains also participate in this interaction, perhaps directly or through another protein factor.

The yeast rRNA gene enhancer does not function by recycling RNA polymerase I and cannot act as a UAS

The mechanism of action of the yeast rRNA gene enhancer was investigated by measuring transcription of an rRNA minigene, cloned into a multicopy plasmid, in transformed yeast. Expression of the minigene was increased when the enhancer was cloned either upstream of or downstream from the minigene. When an enhancer was present both upstream and downstream of the minigene, the upstream element was functionally dominant. The upstream enhancer was active in this construct in the absence of detectable read-through by any RNA polymerase. In a construct containing tandem rRNA minigenes, an enhancer element located between the two promoters activated transcription from both independently. Therefore, the enhancer does not appear to activate transcription by recycling RNA polymerase I molecules to the promoter. The enhancer also failed to activate transcription from the intact promoter of the yeast CYC1 gene, and was unable to functionally substitute for the natural upstream activation sequences (UASs) of this gene. Therefore, the enhancer functions differently to UASs of RNA polymerase II genes, and is probably polymerase-specific.

Two complex regions, including a TATA sequence, are required for transcription by RNA polymerase I in Neurospora crassa

In order to define the RNA polymerase I transcriptional apparatus and how it might interact with regulatory signals, the DNA sequences necessary for 40S rRNA transcription in Neurospora crassa were determined. A systematic set of deletion, substitution and insertion mutations were assayed in a homologous in vitro system. The sequences required for transcription of the gene consist of two large domains (I and II) from -113 to -37, and -29 to +4, respectively. Complete deletion of either domain abolished transcription. Upstream sequences confer a small stimulation of transcription. Domain II includes a TATA sequence at -5 which is sensitive to a small (2 bp) substitution and which is conserved among the large rRNA genes of many organisms. Domain I includes a sequence, termed the 'Ribo box', which is also required for transcription of the Neurospora 5S rRNA genes (1), and which occurs in the 5' region of a Neurospora ribosomal protein gene. The 5S and 40S Ribo boxes are shown to be functionally interchangeable.

Linker scanning of the yeast RNA polymerase I promoter

To define the RNA polymerase I promoter in the rDNA of Saccharomyces cerevisiae more precisely, we have constructed a series of 5'- and 3'-deletion mutants in a novel, plasmid-borne rDNA minigene, that also contains the transcriptional enhancer. Our data show that the Pol I promoter, in this context, extends from position -155 to +27, with 5'-deletions up to -134 and 3'-deletions up to -2 removing essential sequence information. To investigate the internal organization of the yeast Pol I promoter, linker scanning mutants were constructed, that traverse the Pol I promoter region and comprise between 5 and 12 clustered point mutations. Analysis of minigene transcription in yeast cells transformed with these plasmids demonstrates that the pol I promoter consists of three domains. Mutations in Domain I (from position -28 to +8) and Domain II (-70 to -51) drastically reduce promoter activity, whereas clustered point mutations in Domain III (starts at position -146 and presumably extends to position -76) appear to have less effect. Furthermore, the insertion of 4 nt between Domains I and II diminishes minigene transcription, indicating that the relative positions of these domains is essential.

Termination of transcription by yeast RNA polymerase I

Analysis of the termination of transcription by yeast RNA polymerase I (Pol I) using in vitro run-on experiments in both isolated nuclei and permeabilized cells demonstrated that Pol I does not traverse the whole intergenic spacer separating consecutive 37S operons, but terminates transcription before reaching the 5S rRNA gene, that is within NTS 1. In order to discriminate between processing and termination at the 3'-end generating sites previously identified in vivo in NTS 1 (T1, T2 and T3), fragments containing these sites were inserted into the middle of the reporter DNA of an artificial rRNA minigene. RNA isolated from yeast cells transformed with these minigenes was analyzed for the presence of transcripts derived from sequences both up- and downstream of the insert by Northern blot hybridization, reverse transcription analysis and S1 nuclease mapping. In accordance with previously obtained results T1 (+15 to +50) was found to behave as a processing site. T2 (+210) however was concluded to be an efficient, genuine Pol I terminator. In addition to T2, two other terminators were identified in NTS 1: T3A (at +690) and T3B (at +950). Surprisingly, when the 3' terminal part of NTS 2 was tested for its capacity to generate 3'-ends, another terminator (Tp) was found to be present at a position 300 bp upstream of the transcription initiation site of the 37S-rRNA operon.

Transcription by RNA polymerase I stimulates mitotic recombination in Saccharomyces cerevisiae

The recombination-stimulating sequence HOT1 is derived from the ribosomal DNA array of Saccharomyces cerevisiae and corresponds to sequences that promote transcription by RNA polymerase I. When inserted at a chromosomal location outside the ribosomal DNA array, HOT1 stimulates mitotic recombination in the adjacent sequences. To investigate the relationship between transcription and recombination, transcription promoted by HOT1 was directly examined. These studies demonstrated that transcription starts at the RNA polymerase I initiation site in HOT1 and proceeds through the chromosomal sequences in which recombination is enhanced. Linker insertion mutations in HOT1 were generated and assayed for recombination stimulation and for promoter function; this analysis demonstrated that the same sequences are required for both activities. These results indicate that the ability of HOT1 to enhance recombination is related to, and most likely dependent on, its ability to promote transcription.

Transcription by RNA polymerase I stimulates mitotic recombination in Saccharomyces cerevisiae

The recombination-stimulating sequence HOT1 is derived from the ribosomal DNA array of Saccharomyces cerevisiae and corresponds to sequences that promote transcription by RNA polymerase I. When inserted at a chromosomal location outside the ribosomal DNA array, HOT1 stimulates mitotic recombination in the adjacent sequences. To investigate the relationship between transcription and recombination, transcription promoted by HOT1 was directly examined. These studies demonstrated that transcription starts at the RNA polymerase I initiation site in HOT1 and proceeds through the chromosomal sequences in which recombination is enhanced. Linker insertion mutations in HOT1 were generated and assayed for recombination stimulation and for promoter function; this analysis demonstrated that the same sequences are required for both activities. These results indicate that the ability of HOT1 to enhance recombination is related to, and most likely dependent on, its ability to promote transcription.

Synthesis of ribosomes in Saccharomyces cerevisiae

The assembly of a eucaryotic ribosome requires the synthesis of four ribosomal ribonucleic acid (RNA) molecules and more than 75 ribosomal proteins. It utilizes all three RNA polymerases; it requires the cooperation of the nucleus and the cytoplasm, the processing of RNA, and the specific interaction of RNA and protein molecules. It is carried out efficiently and is exquisitely sensitive to the needs of the cell. Our current understanding of this process in the genetically tractable yeast Saccharomyces cerevisiae is reviewed. The ribosomal RNA genes are arranged in a tandem array of 100 to 200 copies. This tandem array has led to unique ways of carrying out a number of functions. Replication is asymmetric and does not initiate from every autonomously replicating sequence. Recombination is suppressed. Transcription of the major ribosomal RNA appears to involve coupling between adjacent transcription units, which are separated by the 5S RNA transcription unit. Genes for many ribosomal proteins have been cloned and sequenced. Few are linked; most are duplicated; most have an intron. There is extensive homology between yeast ribosomal proteins and those of other species. Most, but not all, of the ribosomal protein genes have one or two sites that are essential for their transcription and that bind a common transcription factor. This factor binds also to many other places in the genome, including the telomeres. There is coordinated transcription of the ribosomal protein genes under a variety of conditions. However, the cell seems to possess no mechanism for regulating the transcription of individual ribosomal protein genes in response either to a deficiency or an excess of a particular ribosomal protein. A deficiency causes slow growth. Any excess ribosomal protein is degraded very rapidly, with a half-life of 1 to 5 min. Unlike most types of cells, yeast cells appear not to regulate the translation of ribosomal proteins. However, in the case of ribosomal protein L32, the protein itself causes a feedback inhibition of the splicing of the transcript of its own gene. The synthesis of ribosomes involves a massive transfer of material across the nuclear envelope in both directions. Nuclear localization signals have been identified for at least three ribosomal proteins; they are similar but not identical to those identified for the simian virus 40 T antigen. There is no information about how ribosomal subunits are transported from the nucleus to the cytoplasm.(ABSTRACT TRUNCATED AT 400 WORDS)

A system for the analysis of yeast ribosomal DNA mutations

To develop a system for the analysis of eucaryotic ribosomal DNA (rDNA) mutations, we cloned a complete, transcriptionally active rDNA unit from the yeast Saccharomyces cerevisiae on a centromere-containing yeast plasmid. To distinguish the plasmid-derived ribosomal transcripts from those encoded by the rDNA locus, we inserted a tag of 18 base pairs within the first expansion segment of domain I of the 26S rRNA gene. We demonstrate that this insertion behaves as a neutral mutation since tagged 26S rRNA is normally processed and assembled into functional ribosomal subunits. This system allows us to study the effect of subsequent mutations within the tagged rDNA unit on the biosynthesis and function of the rRNA. As a first application, we wanted to ascertain whether the assembly of a 60S subunit is dependent on the presence in cis of an intact 17S rRNA gene. We found that a deletion of two-thirds of the 17S rRNA gene has no effect on the accumulation of active 60S subunits derived from the same operon. On the other hand, deletions within the second domain of the 26S rRNA gene completely abolished the accumulation of mature 26S rRNA.

A system for the analysis of yeast ribosomal DNA mutations

To develop a system for the analysis of eucaryotic ribosomal DNA (rDNA) mutations, we cloned a complete, transcriptionally active rDNA unit from the yeast Saccharomyces cerevisiae on a centromere-containing yeast plasmid. To distinguish the plasmid-derived ribosomal transcripts from those encoded by the rDNA locus, we inserted a tag of 18 base pairs within the first expansion segment of domain I of the 26S rRNA gene. We demonstrate that this insertion behaves as a neutral mutation since tagged 26S rRNA is normally processed and assembled into functional ribosomal subunits. This system allows us to study the effect of subsequent mutations within the tagged rDNA unit on the biosynthesis and function of the rRNA. As a first application, we wanted to ascertain whether the assembly of a 60S subunit is dependent on the presence in cis of an intact 17S rRNA gene. We found that a deletion of two-thirds of the 17S rRNA gene has no effect on the accumulation of active 60S subunits derived from the same operon. On the other hand, deletions within the second domain of the 26S rRNA gene completely abolished the accumulation of mature 26S rRNA.

Organization of the ribosomal RNA genes of Schizophyllum commune

The 18, 5.8, 25 and 5S ribosomal RNA (rRNA) cistrons have been mapped on the ribosomal DNA (rDNA) unit repeat of Schizophyllum commune strain 4-40. These genes are spatially ordered in the sequence given. The presence of a large primary precursor rRNA which is processed to form the mature 18, 5.8 and 25S rRNAs has been demonstrated. We have mapped the site of transcriptional initiation for this rRNA primary precursor. The sequence surrounding this site has been determined and shown to be highly conserved, with considerable identity to those in Neurospora crassa and Dictyostelium discoideum. The direction of transcription of the rRNA genes has been determined. The 5S rRNA cistron is transcribed in the same direction as the other rRNAs, however it is not transcribed as a part of the large primary precursor. The previously identified rDNA strain-specific length polymorphisms (Specht et al. 1984) are shown to be located within the transcribed region of the rDNA unit repeat.

Regular distribution of length heterogeneities within non-transcribed spacer regions of cloned and genomic rDNA of Saccharomyces cerevisiae

A length difference of about 50 bp in the EcoRI fragment B of the rDNA from two different strains of Saccharomyces cerevisiae has been mapped in detail by sequencing of cloned fragments. This 2.4 kb EcoRI fragment contains the start of the 35S rRNA gene at one end and the 5S rRNA gene in the middle flanked by non-transcribed spacers, NTS1 and NTS2. The difference appeared as short deletions or insertions in five regularly spaced regions within the 1 kb NTS1, 3' to the 5S rRNA gene. The same regions of heterogeneities were displayed when all available sequence data of the NTS1 were compared. Four of the variable regions are located 160-170 bp apart, indicating that they might represent linker sequences between phased nucleosomes. Two variant clones, differing in the length of one subfragment of NTS1, were isolated for each strain. In both cases these represented the major variants among chromosomal NTS1 as revealed by sequencing of genomic fragments.