The yeast GAL11 protein is involved in regulation of the structure and the position effect of telomeres

The Mediator complex: a central integrator of transcription

The RNA polymerase II (Pol II) enzyme transcribes all protein-coding and most non-coding RNA genes and is globally regulated by Mediator - a large, conformationally flexible protein complex with a variable subunit composition (for example, a four-subunit cyclin-dependent kinase 8 module can reversibly associate with it). These biochemical characteristics are fundamentally important for Mediator's ability to control various processes that are important for transcription, including the organization of chromatin architecture and the regulation of Pol II pre-initiation, initiation, re-initiation, pausing and elongation. Although Mediator exists in all eukaryotes, a variety of Mediator functions seem to be specific to metazoans, which is indicative of more diverse regulatory requirements.

Genetic and physical interactions between Tel2 and the Med15 Mediator subunit in Saccharomyces cerevisiae

Background

In budding yeast, the highly conserved Tel2 protein is part of several complexes and its main function is now believed to be in the biogenesis of phosphatidyl inositol 3-kinase related kinases.

Principal Findings

To uncover potentially novel functions of Tel2, we set out to isolate temperature-sensitive (ts) mutant alleles of TEL2 in order to perform genetic screenings. MED15/GAL11, a subunit of Mediator, a general regulator of transcription, was isolated as a suppressor of these mutants. The isolated tel2 mutants exhibited a short telomere phenotype that was partially rescued by MED15/GAL11 overexpression. The tel2-15mutant was markedly deficient in the transcription of EST2, coding for the catalytic subunit of telomerase, potentially explaining the short telomere phenotype of this mutant. In parallel, a two-hybrid screen identified an association between Tel2 and Rvb2, a highly conserved member of the AAA+ family of ATPases further found by in vivo co-immunoprecipitation to be tight and constitutive. Transiently overproduced Tel2 and Med15/Gal11 associated together, suggesting a potential role for Tel2 in transcription. Other Mediator subunits, as well as SUA7/TFIIB, also rescued the tel2-ts mutants.

Significance

Altogether, the present data suggest the existence of a novel role for Tel2, namely in transcription, possibly in cooperation with Rvb2 and involving the existence of physical interactions with the Med15/Gal11 Mediator subunit.

The tail-module of yeast Mediator complex is required for telomere heterochromatin maintenance

Eukaryotic chromosome ends have a DNA-protein complex structure termed telomere. Integrity of telomeres is essential for cell proliferation. Genome-wide screenings for telomere length maintenance genes identified several components of the transcriptional regulator, the Mediator complex. Our work provides evidence that Mediator is involved in telomere length regulation and telomere heterochromatin maintenance. Tail module of Mediator is required for telomere silencing by promoting or stabilizing Sir protein binding and spreading on telomeres. Mediator binds on telomere and may be a component of telomeric chromatin. Our study reveals a specific role of Mediator complex at the heterochromatic telomere and this function is specific to telomeres as it has no effect on the HMR locus.

Restoration of silencing in Saccharomyces cerevisiae by tethering of a novel Sir2-interacting protein, Esc8

We previously described two classes of SIR2 mutations specifically defective in either telomeric/HM silencing (class I) or rDNA silencing (class II) in S. cerevisiae. Here we report the identification of genes whose protein products, when either overexpressed or directly tethered to the locus in question, can establish silencing in SIR2 class I mutants. Elevated dosage of SCS2, previously implicated as a regulator of both inositol biosynthesis and telomeric silencing, suppressed the dominant-negative effect of a SIR2-143 mutation. In a genetic screen for proteins that restore silencing when tethered to a telomere, we isolated ESC2 and an uncharacterized gene, (YOL017w), which we call ESC8. Both Esc2p and Esc8p interact with Sir2p in two-hybrid assays, and the Esc8p-Sir2 interaction is detected in vitro. Interestingly, Esc8p has a single close homolog in yeast, the ISW1-complex factor Ioc3p, and has also been copurified with Isw1p, raising the possibility that Esc8p is a component of an Isw1p-containing nucleosome remodeling complex. Whereas esc2 and esc8 deletion mutants alone have only marginal silencing defects, cells lacking Isw1p show a strong silencing defect at HMR but not at telomeres. Finally, we show that Esc8p interacts with the Gal11 protein, a component of the RNA pol II mediator complex.

Negative regulation of transcription by the yeast global transcription factors, Gal11 and Sin4

Gal11 and Sin4 proteins are yeast global transcription factors that regulate transcription of a variety of genes, both positively and negatively. Gal11, in a major part, functions in the activation of transcription, whereas Sin4 has an opposite role, yet they are reported to be present as a complex in the so-called RNA polymerase II holoenzyme. To reveal howthese auxiliary factors participate in switching transcription on and off, a complex formation between Gal11 and Sin4 and its effect on the negative regulation of transcription were studied. Using an artificial promoter that is negatively regulated by Gal11, it was shown that the presence of Sin4 or Pgd1/Hrs1/Med3 was required for Gal11 to repress both basal and activated transcription. Genetic and biochemical studies using a temperature-sensitive Gal11 mutant showed that the amino acid region 866-910 essential for Gal11 function was also important for repression of transcription and a complex formation with Sin4. Analysis with dam methylase accessibility to the promoter region suggested that nucleosome structure may be involved in negative regulation. Based on these results, possible mechanisms by which a mediator subcomplex regulates transcription is discussed.

Telomere structure, replication and length maintenance

Telomeres are the termini of linear eukaryotic chromosomes consisting of tandem repeats of DNA and proteins that bind to these repeat sequences. Telomeres ensure the complete replication of chromosome ends, impart protection to ends from nucleolytic degradation, end-to-end fusion, and guide the localization of chromosomes within the nucleus. In addition, a combination of genetic, biochemical, and molecular biological approaches have implicated key roles for telomeres in diverse cellular processes such as regulation of gene expression, cell division, cell senescence, and cancer. This review focuses on recent advances in our understanding of the organization of telomeres, telomere replication, proteins that bind telomeric DNA, and the establishment of telomere length equilibrium.

Genetics of transcriptional regulation in yeast: connections to the RNA polymerase II CTD

Transcriptional regulation is important in all eukaryotic organisms for cell growth, development, and responses to environmental change. Saccharomyces cerevisiae, or bakers' yeast, has provided a powerful system for genetic analysis of transcriptional regulation, and findings from the study of this model system have proven broadly applicable to higher organisms. Transcriptional regulation requires the interactions of regulatory proteins with various components of the transcription machinery. Recently, genetic analysis of a diverse set of transcriptional regulatory responses has converged with studies of the function of the RNA polymerase II carboxy-terminal domain (CTD) to reveal regulatory roles for proteins associated with the CTD. These proteins, designated Srb/mediator proteins, are broadly involved in both positive and negative regulatory responses in vivo. This review focuses on the connections between genetic analysis of transcriptional regulation and the functions of the Srb/mediator proteins associated with the RNA polymerase II CTD.

The yeast HRS1 gene is involved in positive and negative regulation of transcription and shows genetic characteristics similar to SIN4 and GAL11

We provide genetic evidence that HRS1/PGD1, a yeast gene previously identified as a suppressor of the hyper-recombination phenotype of hpr1, has positive and negative roles in transcriptional regulation. We have analyzed three differently regulated promoters, GAL1, PHO5 and HSP26, by beta-galactosidase assays of lacZ-fused promoters and by Northern analysis of the endogenous genes. Transcription of these promoters was derepressed in hrs1delta mutants under conditions in which it is normally repressed in wild type. Under induced conditions it was either strongly reduced or significantly enhanced depending on the promoter system analyzed. Constitutive transcription was not affected, as determined in ADH1 and TEF2. In addition, Hrs1p was required for mating-factor expression, telomere-linked DNA silencing and DNA supercoiling of plasmids. Furthermore, hrs1delta suppressed Ty-insertion mutations and conferred a Gal- phenotype. Many of these phenotypes also result from mutations in GAL11, SIN4 or RGR1, which encode proteins of the RNA polII mediator. We also show that gal11delta and sin4delta partially suppress the hyper-rec phenotype of hpr1 mutants, although to a lesser extent than hrs1delta. Our results provide new evidence for the connection between hpr1delta-induced deletions and transcription. We discuss the possibility that Hrs1p might be a component of the RNA polII transcription machinery.

The chromosome ends of Saccharomyces cerevisiae

Yeast chromosome ends are similar in structure and function to chromosome ends in most, if not all, eukaryotic organisms. There is a G-rich terminal repeat at the ends which is maintained by telomerase. In addition to the classical functions of protecting the end from degradation and end-to-end fusions, and completing replication, yeast telomeres have several interesting properties including: non-nucleosomal chromatin structure; transcriptional position effect variegation for genes with adjacent telomeres; nuclear peripheral localization; apparent physical clustering; non-random recombinational interactions. A number of genes have been identified that are involved in modifying one or more of these properties. These include genes involved in general DNA metabolism, chromatin structure and telomere maintenance. Adjacent to the terminal repeat is a mosaic of middle repetitive elements that exhibit a great deal of polymorphism both between individual strains and among different chromosome ends. Much of the sequence redundancy in the yeast genome is found in the sub-telomeric regions (within the last 25 kb of each end). The sub-telomeric regions are generally low in gene density, low in transcription, low in recombination, and they are late replicating. The only element which appears to be shared by all chromosome ends is part of the previously defined X element containing an ARS consensus. Most of the 'core' X elements also contain an Abf1p binding site and a URS1-like element, which may have consequences for the chromatin structure, nuclear architecture and transcription of native telomeres. Possible functions of sub-telomeric repeats include: fillers for increasing chromosome size to some minimum threshold level necessary for chromosome stability; barrier against transcriptional silencing; a suitable region for adaptive amplification of genes; secondary mechanism of telomere maintenance via recombination when telomerase activity is absent.

Positive and negative transcriptional regulation by the yeast GAL11 protein depends on the structure of the promoter and a combination of cis elements

GAL11 was first identified as a gene required for full expression of some galactose-inducible genes that are activated by GAL4, and it was subsequently shown to be necessary for full expression of another set of genes activated by RAP1/GRF1/TUF. Genetic analysis suggests that GAL11 functions as a coactivator, mediating the interaction of sequence-specific activators with basal transcription factors. To test this hypothesis, we first tried to identify functional domains by deletion analysis and found that the 866-910 region is indispensable for function. Using reporters bearing various upstream activating sequences (UAS) and different core promoter structures, we show that the involvement of GAL11 in transcriptional activation varies with the target promoter and the particular combination of cis elements. Gel electrophoresis in the presence of chloroquine shows that GAL11 affects the chromatin structure of a circular plasmid. Based on these findings, the role of GAL11 in regulation of transcription, including an alteration in chromatin structure, is discussed.