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

Dissecting the regulatory circuitry of a eukaryotic genome

Genome-wide expression analysis was used to identify genes whose expression depends on the functions of key components of the transcription initiation machinery in yeast. Components of the RNA polymerase II holoenzyme, the general transcription factor TFIID, and the SAGA chromatin modification complex were found to have roles in expression of distinct sets of genes. The results reveal an unanticipated level of regulation which is superimposed on that due to gene-specific transcription factors, a novel mechanism for coordinate regulation of specific sets of genes when cells encounter limiting nutrients, and evidence that the ultimate targets of signal transduction pathways can be identified within the initiation apparatus.

Identification of new mediator subunits in the RNA polymerase II holoenzyme from Saccharomyces cerevisiae

Mediator was isolated from yeast on the basis of its requirement for transcriptional activation in a fully defined system. We have now identified three new members of mediator in the low molecular mass range by peptide sequence determination. These are the products of the NUT2, CSE2, and MED11 genes. The product of the NUT1 gene is evidently a component of mediator as well. NUT1 and NUT2 were earlier identified as negative regulators of the HO promoter, whereas mutations in CSE2 affect chromosome segregation. MED11 is a previously uncharacterized gene. The existence of these proteins in the mediator complex was verified by copurification and co-immunoprecipitation with RNA polymerase II holoenzyme.

Srb/mediator proteins interact functionally and physically with transcriptional repressor Sfl1

Srb/mediator proteins that are associated with RNA polymerase II holoenzyme have been implicated in transcriptional repression in Saccharomyces cerevisiae. We show here that the defect in repression of SUC2 caused by mutation of SRB8, SRB9, SRB11, SIN4 or ROX3 is suppressed by increased dosage of the SFL1 gene, and the genetic behavior of the sfl1Delta mutation provides further evidence for a functional relationship. Sfl1 acts on SUC2 through a repression site located immediately 5' to the TATA box, and Sfl1 binds this DNA sequence in vitro. Moreover, LexA-Sfl1 represses transcription of a reporter, and repression is reduced in an srb9 mutant. Finally, we show that Sfl1 co-immunoprecipitates from cell extracts with Srb9, Srb11, Sin4 and Rox3. We propose that Sfl1, when bound to its site, interacts with Srb/mediator proteins to inhibit transcription by RNA polymerase II holoenzyme.

Regulatory targets in the RNA polymerase II holoenzyme

The RNA polymerase II holoenzyme is the form of polymerase recruited to promoters for protein-coding genes. Several targets of mammalian activators, previously called coactivators, turn out to be subunits of the holoenzyme which activators use to recruit and regulate the holoenzyme. Several of these newly identified holoenzyme components have been implicated in human disease.

A novel yeast protein influencing the response of RNA polymerase II to transcriptional activators

A sensitive in vitro crosslinking technique using a photoactive derivative of the chimeric activator LexA-E2F-1 was used to identify yeast proteins that might influence the response of RNA polymerase II to transcriptional activators. We found that a novel yeast protein, Xtc1p, could be covalently crosslinked to the activation domain of LexA-E2F-1 when this derivatized activator was bound to DNA upstream of an activator-responsive RNA polymerase II promoter. Because affinity chromatography experiments showed that Xtc1p also bound directly and specifically to the activation domains of E2F-1, the viral activator VP16, and the yeast activator Gal4p and copurified with the RNA polymerase II holoenzyme complex, Xtc1p may modulate the response of RNA polymerase II to multiple activators. Consistent with this notion, yeast strains deleted for the XTC1 gene exhibited pleiotropic growth defects, including temperature sensitivity, galactose auxotrophy, and a heightened sensitivity to activator overexpression, as well as an altered response to transcriptional activators in vivo.

Spe3, which encodes spermidine synthase, is required for full repression through NRE(DIT) in Saccharomyces cerevisiae

We previously identified a transcriptional regulatory element, which we call NRE(DIT), that is required for repression of the sporulation-specific genes, DIT1 and DIT2, during vegetative growth of Saccharomyces cerevisiae. Repression through this element is dependent on the Ssn6-Tup1 corepressor. In this study, we show that SIN4 contributes to NRE(DIT)-mediated repression, suggesting that changes in chromatin structure are, at least in part, responsible for regulation of DIT gene expression. In a screen for additional genes that function in repression of DIT (FRD genes), we recovered alleles of TUP1, SSN6, SIN4, and ROX3 and identified mutations comprising eight complementation groups of FRD genes. Four of these FRD genes appeared to act specifically in NRE(DIT)mediated repression, and four appeared to be general regulators of gene expression. We cloned the gene complementing the frd3-1 phenotype and found that it was identical to SPE3, which encodes spermidine synthase. Mutant spe3 cells not only failed to support complete repression through NRE(DIT) but also had modest defects in repression of some other genes. Addition of spermidine to the medium partially restored repression to spe3 cells, indicating that spermidine may play a role in vivo as a modulator of gene expression. We suggest various mechanisms by which spermidine could act to repress gene expression.

A human RNA polymerase II complex containing factors that modify chromatin structure

We have isolated a human RNA polymerase II complex that contains chromatin structure remodeling activity and histone acetyltransferase activity. This complex contains the Srb proteins, the Swi-Snf complex, and the histone acetyltransferases CBP and PCAF in addition to RNA polymerase II. Notably, the general transcription factors are absent from this complex. The complex was purified by two different methods: conventional chromatography and affinity chromatography using antibodies directed against CDK8, the human homolog of the yeast Srb10 protein. Protein interaction studies demonstrate a direct interaction between RNA polymerase II and the histone acetyltransferases p300 and PCAF. Importantly, p300 interacts specifically with the nonphosphorylated, initiation-competent form of RNA polymerase II. In contrast, PCAF interacts with the elongation-competent, phosphorylated form of RNA polymerase II.

Activated transcription independent of the RNA polymerase II holoenzyme in budding yeast

We investigated whether the multisubunit holoenzyme complex of RNA polymerase II (Pol II) and mediator is universally required for transcription in budding yeast. DeltaCTD Pol II lacking the carboxy-terminal domain of the large subunit cannot assemble with mediator but can still transcribe the CUP1 gene. CUP1 transcripts made by DeltaCTD Pol II initiated correctly and some extended past the normal poly(A) site yielding a novel dicistronic mRNA. Most CUP1 transcripts made by DeltaCTD Pol II were degraded but could be stabilized by deletion of the XRN1 gene. Unlike other genes, transcription of CUP1 and HSP82 also persisted after inactivation of the CTD kinase Kin28 or the mediator subunit Srb4. The upstream-activating sequence (UAS) of the CUP1 promoter was sufficient to drive Cu2+ inducible transcription without Srb4 and heat shock inducible transcription without the CTD. We conclude that the Pol II holoenzyme is not essential for all UAS-dependent activated transcription in yeast.

Targeting of CDK8 to a promoter-proximal RNA element demonstrates catalysis-dependent activation of gene expression

During transcription of mRNA genes, there is a correlation between the phosphorylation state of the C-terminal domain (CTD) of the large subunit of RNA polymerase II (RNAP II) and the ability of the RNAP II complex to processively transcribe the gene. To examine the involvement of CTD phosphorylation in modulation of RNAP II function, we have analyzed the ability of a known CTD kinase, human Cdk8, to modulate HIV-1 LTR-driven gene expression upon directed targeting to a promoter-proximal nascent RNA element. The results indicated that Cdk8, when localized to an RNA element, activates gene expression in a catalysis-dependent manner. Also, Cdk8 targeted to RNA was observed to act in a synergystic manner with DNA-targeted Sp1 but not with DNA-targeted HIV-1 Tat, suggesting that RNA-targeted Cdk8 acts on similar rate limiting post-initiation events as Tat. As recent observations suggest that Tat/TAR-mediated transcription of the proviral genome of HIV depends on specific phosphorylation of RNAP II in its CTD by the Tat-associated kinase (TAK/p-TEFb/Cdk9), our results indicate that Cdk8 shares with Cdk9 the ability to modulate transcription upon targeting to a nascent RNA element.

NAT, a human complex containing Srb polypeptides that functions as a negative regulator of activated transcription

A complex that represses activated transcription and contains the human homologs of the yeast Srb7, Srb10, Srb11, Rgr1, and Med6 proteins was isolated. The complex is devoid of the Srb polypeptides previously shown to be components of the yeast Mediator complex that functions in transcriptional activation. The complex phosphorylates the CTD of RNA polymerase II (RNAPII) at residues other than those phosphorylated by the kinase of TFIIH. Moreover, the complex specifically interacts with RNAPII. The interaction is not mediated by the CTD of RNAPII, but is precluded by phosphorylation of the CTD. Our results indicate that the complex is a subcomplex of the human RNAPII holoenzyme. We suggest that the RNAPII holoenzyme is a transcriptional control panel, integrating and responding to specific signals to activate or repress transcription.

Life with nucleosomes: chromatin remodelling in gene regulation

In the past year, the role of chromatin has emerged at the forefront of transcription research. Discovery and characterisation of the chromatin modifying machinery have significantly advanced our understanding of the molecular activities that establish a transcriptionally competent substrate in vivo, and have underscored the importance of the part played by chromatin in the regulation of transcription.

Molecular genetics of the RNA polymerase II general transcriptional machinery

Transcription initiation by RNA polymerase II (RNA pol II) requires interaction between cis-acting promoter elements and trans-acting factors. The eukaryotic promoter consists of core elements, which include the TATA box and other DNA sequences that define transcription start sites, and regulatory elements, which either enhance or repress transcription in a gene-specific manner. The core promoter is the site for assembly of the transcription preinitiation complex, which includes RNA pol II and the general transcription fctors TBP, TFIIB, TFIIE, TFIIF, and TFIIH. Regulatory elements bind gene-specific factors, which affect the rate of transcription by interacting, either directly or indirectly, with components of the general transcriptional machinery. A third class of transcription factors, termed coactivators, is not required for basal transcription in vitro but often mediates activation by a broad spectrum of activators. Accordingly, coactivators are neither gene-specific nor general transcription factors, although gene-specific coactivators have been described in metazoan systems. Transcriptional repressors include both gene-specific and general factors. Similar to coactivators, general transcriptional repressors affect the expression of a broad spectrum of genes yet do not repress all genes. General repressors either act through the core transcriptional machinery or are histone related and presumably affect chromatin function. This review focuses on the global effectors of RNA polymerase II transcription in yeast, including the general transcription factors, the coactivators, and the general repressors. Emphasis is placed on the role that yeast genetics has played in identifying these factors and their associated functions.

Functional relationships of Srb10-Srb11 kinase, carboxy-terminal domain kinase CTDK-I, and transcriptional corepressor Ssn6-Tup1

The Srb10-Srb11 protein kinase of Saccharomyces cerevisiae is a cyclin-dependent kinase (cdk)-cyclin pair which has been found associated with the carboxy-terminal domain (CTD) of RNA polymerase II holoenzyme forms. Previous genetic findings implicated the Srb10-Srb11 kinase in transcriptional repression. Here we use synthetic promoters and LexA fusion proteins to test the requirement for Srb10-Srb11 in repression by Ssn6-Tup1, a global corepressor. We show that srb10delta and srb11delta mutations reduce repression by DNA-bound LexA-Ssn6 and LexA-Tup1. A point mutation in a conserved subdomain of the kinase similarly reduced repression, indicating that the catalytic activity is required. These findings establish a functional link between Ssn6-Tup1 and the Srb10-Srb11 kinase in vivo. We also explored the relationship between Srb10-Srb11 and CTD kinase I (CTDK-I), another member of the cdk-cyclin family that has been implicated in CTD phosphorylation. We show that mutation of CTK1, encoding the cdk subunit, causes defects in transcriptional repression by LexA-Tup1 and in transcriptional activation. Analysis of the mutant phenotypes and the genetic interactions of srb10delta and ctk1A suggests that the two kinases have related but distinct roles in transcriptional control. These genetic findings, together with previous biochemical evidence, suggest that one mechanism of repression by Ssn6-Tup1 involves functional interaction with RNA polymerase II holoenzyme.

Essential functional interactions of SAGA, a Saccharomyces cerevisiae complex of Spt, Ada, and Gcn5 proteins, with the Snf/Swi and Srb/mediator complexes

The Saccharomyces cerevisiae transcription factor Spt20/Ada5 was originally identified by mutations that suppress Ty insertion alleles and by mutations that suppress the toxicity caused by Gal4-VP16 overexpression. Here we present evidence for physical associations between Spt20/Ada5 and three other Spt proteins, suggesting that they exist in a complex. A related study demonstrates that this complex also contains the histone acetyltransferase, Gcn5, and Ada2. This complex has been named SAGA (Spt/Ada/Gcn5 acetyltransferase). To identify functions that genetically interact with SAGA, we have screened for mutations that cause lethality in an spt20 delta/ada5 delta mutant. Our screen identified mutations in SNF2, SIN4, and GAL11. These mutations affect two known transcription complexes: Snf/Swi, which functions in nucleosome remodeling, and Srb/mediator, which is required for regulated transcription by RNA polymerase II. Systematic analysis has demonstrated that spt20 delta/ada5 delta and spt7 delta mutations cause lethality with every snf/swi and srb/mediator mutation tested. Furthermore, a gcn5 delta mutation causes severe sickness with snf/swi mutations, but not with srb/mediator mutations. These findings suggest that SAGA has multiple activities and plays critical roles in transcription by RNA polymerase II.