Project description:Functional studies of the Yeast Mediator Tail Module Subunits

Project description:The Mediator is composed of multiple of proteins in the head, body, tail and CDK subunits conserved from yeast to humans. However, not all the components are required for transcription. Components of the tail subunit are not essential but to varying degrees are required for changes in transcription to stress. While some stresses are familiar such as heat, desiccation, and starvation, others are exotic yet elicit a physical stress response. MCHM is a hydrotrope that induces growth arrest in yeast. By exploiting genetic variation, specifically in Med15, between yeast strains, we found that Med15 with the polyQ expansion conferred MCHM sensitivity. This sensitivity was not from a loss of function as the reciprocal hemizygous hybrids were all sensitive, suggesting that there is an incompatibility between Mediator complexes from genetic divergent yeast strains. Transcriptomics from yeast expressing the incompatible Med15 changed expression in diverse pathways. Expansion of polyQ tracts in Med15 resulted in multiple isoforms which were mostly from likely post-translational modifications. Stability of Med15 was dependent on Ydj1, a chaperone and the incompatible Med15 allele was expressed at lower levels and less stable than the compatible Med15 allele. Med15 is tethered to the rest of the Mediator complex via Med2 and 3. Deletion of either Med2 or Med3 changes the Med15 isoform patterns in the in a similar manner whereas deletion of Med5, a distal component of the tail did not change the pattern. The med2 and 3 mutants are similarly sensitive to MCHM while med5 mutants are not. Differences between the Med15 alleles extend to responses to different stresses. Whereas the incompatible allele of Med15 improved growth to chemicals that produce free radicals, and the compatible allele of Med15 improved growth to reducing agents, caffeine, and hydroxyurea. This may reflect the positive and negative role that Med15 has in transcription.

Project description:The yeast Mediator complex can be divided into three modules, designated Head, Middle and Tail. Tail comprises the Med2, Med3, Med5, Med15 and Med16 protein subunits, which are all encoded by genes that are individually non-essential for viability. In cells lacking Med16, Tail is displaced from Head and Middle. However, inactivation of MED5/MED15 and MED15/MED16 are synthetically lethal, indicating that Tail performs essential functions as a separate complex even when it is not bound to Middle and Head. We have used the N-Degron method to create temperature sensitive (ts) mutants in the Mediator tail subunits Med5, Med15 and Med16 to study the immediate effects on global gene expression when each subunit is individually inactivated, and when MED5/15 or MED15/16 are inactivated together.

Project description:The yeast Mediator complex can be divided into three modules, designated Head, Middle and Tail. Tail comprises the Med2, Med3, Med5, Med15 and Med16 protein subunits, which are all encoded by genes that are individually non-essential for viability. In cells lacking Med16, Tail is displaced from Head and Middle. However, inactivation of MED5/MED15 and MED15/MED16 are synthetically lethal, indicating that Tail performs essential functions as a separate complex even when it is not bound to Middle and Head. We have used the N-Degron method to create temperature sensitive (ts) mutants in the Mediator tail subunits Med5, Med15 and Med16 to study the immediate effects on global gene expression when each subunit is individually inactivated, and when MED5/15 or MED15/16 are inactivated together. All Degron constructs were expressed from their normal chromosomal location under the control of their respective endogenous promoters. We isolated RNA from each strain as early as 45 minutes after changing from the permissive to the restrictive growth conditions to minimize possible secondary effects on gene expression that are not directly caused by the Degron construct(s).

Project description:This study has determined structure of transcription initiation complexes including a DNA-bound activator, RNA polymerase II (Pol II), and Mediator on a divergent promoter GAL80/SUT719 using a combination of cryo-EM and XL-MS analyses. Our cryo-EM single-particle analysis reveals a dimeric form of Med-PIC through the Mediator Tail module induced by the activator protein. Density of the upstream DNA bound to the Gal4-VP16 was identifiable along the Mediator Tail module, while XL-MS localized flexible regions that were not visible by cryo-EM analysis, such as activator-binding domains (ABDs and KIX).

Project description:Tail and Kinase Modules Differently Regulate Core Mediator Recruitment and Function In Vivo

Project description:The multiprotein Mediator complex is an important regulator of RNA polymerase II-dependent genes in eukaryotic cell. In contrast to the situation in many other eukaryotes, the conserved Med15 protein is not a stable component of Mediator isolated from fission yeast. We now demonstrate that Med15 exists in a protein complex together with Hrp1, an ATP-dependent chromatin remodeling protein. The Med15/Hrp1 subcomplex is not a component of the core Mediator complex, but can interact with the repressive L-Mediator conformation. Deletion of MED15 and HRP1 cause similar effects on global steady-state levels of mRNA, but only MED15 is required for galactose-dependent activation of the inv1 gene. Hrp1 has been found in complex with other proteins and genome-wide analysis demonstrates that Med15 only associates with a distinct subset of Hrp1-bound gene promoters. Global analysis reveals that Hrp1-binding normally is associated with increased histone H3 density, but at promoters also bound by Med15, histone H3 density is instead increased. Our findings reveal that Med15 functions as a separate entity in fission yeast and indicate that the function and organization of the Mediator complex may differ significantly between eukaryotes. Keywords: ChIP-chip

Project description:Genome architecture in budding yeast

Project description:Eukaryotic RNA polymerase II (RNAPII) transcribes mRNA genes and non-protein coding RNAs (ncRNAs) including small nuclear and nucleolar RNAs (sn/snoRNAs). In metazoans, RNAPII transcription of sn/snoRNAs is facilitated by a number of specialized complexes, but no such complexes have been discovered in yeast. It has been proposed that yeast sn/snoRNA promoters use the same factors as mRNA promoters, but the extent to which regulators of mRNA genes function at yeast sn/snoRNA genes is unclear. Here, we investigated a potential role for the Mediator complex, essential for mRNA gene transcription, in the transcription of sn/snoRNA genes. We found that the Mediator maps to most sn/snoRNA gene regulatory regions and that rapid depletion of the essential structural subunit Med14 strongly reduces RNAPII and TFIIB occupancy as well as nascent transcription of sn/snoRNA genes. Deletion of Med3 and Med15, subunits of the activator-interacting Mediator tail module, does not affect Mediator recruitment to or RNAPII and TFIIB occupancy of sn/snoRNA genes. Our analyses suggest that Mediator promotes PIC formation and transcription at sn/snoRNA genes, expanding the role of this critical regulator beyond its known functions in mRNA gene transcription and demonstrating further mechanistic similarity between the transcription of mRNA and sn/snoRNA genes.

Project description:Our mechanistic understanding of Mediator derives largely from studies of the 25-subunit yeast complex. Here we combine CRISPR-Cas9 genetic screens, degron assays, in situ Hi-C, and cryo-EM to dissect the function and structure of the 33-subunit mammalian Mediator (mMED). Deletion analyses in B, T and ES cells reveal that depletion of the entire complex blocks PolII recruitment genome-wide, while loss of non-essential subunits, including the Tail module, primarily affects promoters linked to multiple enhancers. Contrary to current models, we find that mMED is not required to tether regulatory DNA, a topological activity controlled predominantly by architectural proteins. Structurally, we show that alterations in the Tail module, particularly at the core-Tail interphase, effect crucial mMED-PolII contacts, providing a rationale for how TFs stabilize the mMED-PolII holoenzyme and promote gene expression. Our studies therefore reveal key insights into how Mediator functionally bridge promoters and enhancers to regulate transcription initiation in higher eukaryotes.