Mediator is an intrinsic component of the basal RNA polymerase II machinery in vivo.

Mediator is a prominent multisubunit coactivator that functions as a bridge between gene-specific activators and the basal RNA polymerase (Pol) II initiation machinery. Here, we study the poorly documented role of Mediator in basal, or activator-independent, transcription in vivo. We show that Mediator is still present at the promoter when the Pol II machinery is recruited in the absence of an activator, in this case through a direct fusion between a basal transcription factor and a heterologous DNA binding protein bound to the promoter.

Transcriptional plasticity through differential assembly of a multiprotein activation complex.

Cell adaptation to the environment often involves induction of complex gene expression programs under the control of specific transcriptional activators. For instance, in response to cadmium, budding yeast induces transcription of the sulfur amino acid biosynthetic genes through the basic-leucine zipper activator Met4, and also launches a program of substitution of abundant glycolytic enzymes by isozymes with a lower content in sulfur. We demonstrate here that transcriptional induction of PDC6, which encodes a pyruvate decarboxylase isoform with low sulfur content, is directly controlled by Met4 and its DNA-binding cofactors the basic-helix-loop-helix protein Cbf1 and the two homologous zinc finger proteins Met31 and Met32.

Substrate-mediated remodeling of methionine transport by multiple ubiquitin-dependent mechanisms in yeast cells.

Plasma membrane transport of single amino-acid methionine in yeast is shown to be mediated by at least seven different permeases whose activities are transcriptionaly and post-transcriptionaly regulated by different ubiquitin-dependent mechanisms. Upon high extracellular methionine exposure, three methionine-permease genes are repressed while four others are induced. SCF(Met30), SCF(Grr1) and Rsp5 ubiquitin ligases are the key actors of the ubiquitin-dependent remodeling of methionine transport.

Inducible dissociation of SCF(Met30) ubiquitin ligase mediates a rapid transcriptional response to cadmium.

Activity of the Met4 transcription factor is antagonized by the SCF(Met30) ubiquitin ligase by degradation-dependent and degradation-independent mechanisms, in minimal and rich nutrient conditions, respectively. In this study, we show that the heavy metal Cd2+ over-rides both mechanisms to enable rapid Met4-dependent induction of metabolic networks needed for production of the antioxidant and Cd2+-chelating agent glutathione. Cd2+ inhibits SCF(Met30) activity through rapid dissociation of the F-box protein Met30 from the holocomplex.

Dual regulation of the met4 transcription factor by ubiquitin-dependent degradation and inhibition of promoter recruitment.

The ubiquitin system has been recently implicated in various aspects of transcriptional regulation, including proteasome-dependent degradation of transcriptional activators. In yeast, the activator Met4 is inhibited by the SCF(Met30) ubiquitin ligase, which recognizes and oligo-ubiquitylates Met4. Here, we demonstrate that in minimal media, Met4 is ubiquitylated and rapidly degraded in response to methionine excess, whereas in rich media, Met4 is oligo-ubiquitylated but remains stable.