Project description:We have analyzed the global effect of the conserved transcription-mRNA export factor Sus1 on transcription and its association with chromatin. We used genomic run-on experiments to show that Sus has a broad impact on the stability of most RNA polymerase II-transcribed genes. Genome association of Sus1 by the chromatin immunoprecipitation technique showed that Sus1 was widely distributed throughout coding regions, tending to accumulate towards the 3’ ends of highly transcribed transcription factor IID (TFIID) and Spt-Ada-Gcn5 acetyltransferase (SAGA) dependent genes. This accumulation depends on growth conditions, the transcriptional rate and whether the genes are TFIID- or SAGA-regulated. Validation of Sus1 occupancy data also revealed that Sus1 appears at tRNAs. Concomitantly, deletion of SUS1 leads to tRNA overexpression. In addition, we discovered that distinctive SAGA subunits Spt8 and Spt7 play a key role in Sus1 enrichment at the 3’ ends of SAGA-regulated genes upon temperature shift and at tRNAs. Thus, our study identifies the molecular mechanisms by which a SAGA factor is recruited genome-wide, and provides evidence of a more general role for this conserved coactivator in eukaryotic transcription. Genome wide analysis of Sus1 in wild type and Spt7 and Spt8 deletion mutants using ChIP-exo and genomic run-on experiments

Project description:Eukaryotic transcription is regulated through two complexes, the general transcription factor IID (TFIID) and the coactivator Spt-Ada-Gcn5 acetyltransferase (SAGA). Recent findings confirm that both TFIID and SAGA contribute to the synthesis of nearly all transcripts and are recruited genome-wide in yeast. However, how this broad recruitment confers selectivity under specific conditions remains an open question. Here we find that the SAGA DUBm subunit Sus1 associates upstream regulatory regions of many yeast genes and that heat shock drastically changes Sus1 binding pattern. While Sus1 binding to TFIID-dominated genes is not affected by temperature, its recruitment to SAGA-dominated genes and RP genes is significantly disturbed under heat shock, being Sus1 relocated to environmental stress responsive genes in these conditions. Moreover, in contrast to recent results showing that SAGA deubiquitinating enzyme Ubp8 is dispensable for RNA synthesis, genomic run-on experiments demonstrate that Sus1 contributes to synthesis and stability for a wide range of transcripts. Our study provides support for a model in which SAGA acts as a global transcriptional regulator in yeast but acquires differential binding affinities under thermal stress conditions.

Project description:The conserved multi-subunit Ccr4-Not complex regulates gene expression in diverse ways. In this work, we characterize the suppression of temperature sensitivity associated with a mutation in the gene encoding the scaffold subunit of the Ccr4-Not complex, NOT1, by the deletion of SPT3. We determine that the deletion of SPT3, but not the deletion of genes encoding other subunits of the SAGA complex, globally suppresses transcriptional defects of not1-2. We find that transcriptional activation in not1-2 is associated with increased binding of TFIID and SAGA at promoters of upregulated genes, and this is suppressed by the deletion of SPT3. Interestingly, Spt3p-dependent activation of transcription occurs in not1-2 even if the SAGA complex is disrupted by the deletion of SPT7 that encodes a subunit of SAGA required for its integrity. Consistent with a SAGA-independent function of Spt3p, the deletion of SPT3 displays synthetic phenotypes when combined with a deletion of SPT7. Taken together, our results provide a new view of the Spt3 protein by identifying a SAGA-independent function of this protein that is functionally linked to the Ccr4-Not complex. Experiment Overall Design: 4 strains were analyzed: the wild type reference strain, two simple mutants (not1-2 and spt3) and one double mutant (not1-2 spt3). All strains were in duplicate.

Project description:The conserved multi-subunit Ccr4-Not complex regulates gene expression in diverse ways. In this work, we characterize the suppression of temperature sensitivity associated with a mutation in the gene encoding the scaffold subunit of the Ccr4-Not complex, NOT1, by the deletion of SPT3. We determine that the deletion of SPT3, but not the deletion of genes encoding other subunits of the SAGA complex, globally suppresses transcriptional defects of not1-2. We find that transcriptional activation in not1-2 is associated with increased binding of TFIID and SAGA at promoters of upregulated genes, and this is suppressed by the deletion of SPT3. Interestingly, Spt3p-dependent activation of transcription occurs in not1-2 even if the SAGA complex is disrupted by the deletion of SPT7 that encodes a subunit of SAGA required for its integrity. Consistent with a SAGA-independent function of Spt3p, the deletion of SPT3 displays synthetic phenotypes when combined with a deletion of SPT7. Taken together, our results provide a new view of the Spt3 protein by identifying a SAGA-independent function of this protein that is functionally linked to the Ccr4-Not complex. Keywords: genetic modification

Project description:Transcriptome analysis of sus1 mutant in reference to its parental wild type reference. Iterative global median method was used for between sample normalization. z-test was performed to evaluate differential gene expression. Keywords: repeat sample

Project description:The SAGA-like complex SLIK is a modified version of the Spt-Ada-Gcn5-Acetyltransferase (SAGA) complex. SLIK is formed through C-terminal truncation of the Spt7 SAGA subunit, causing loss of Spt8 that interacts with the TATA-binding protein. SLIK and SAGA are both coactivators of RNA polymerase II transcription in yeast. In addition, both SAGA and SLIK perform chromatin modifications and the two complexes have been speculated to uniquely contribute to transcription regulation. To test the respective contribution of SAGA vs. SLIK in transcription regulation, we assayed the chromatin modifying functions of SAGA vs. SLIK, revealing identical kinetics on minimal substrates in vitro. Furthermore, we determined a low-resolution cryo-EM structure of SLIK, revealing a modular architecture identical to SAGA. Finally, we performed a comprehensive study of DNA-binding properties of both coactivators. Purified SAGA and SLIK both associate with ssDNA and dsDNA with high affinity (KD = 10-17 nM) and the binding is sequence-independent. In conclusion, our study shows that the cleavage of Spt7 and the absence of Spt8 subunit in SLIK neither drive any major conformational differences in its structure compared to SAGA, nor significantly affect HAT, DUB or DNA binding activities in vitro.

Project description:Transcriptome analysis of sus1 mutant in reference to its parental wild type reference. Iterative global median method was used for between sample normalization. z-test was performed to evaluate differential gene expression.

Project description:In Saccharomyces cerevisiae, the SAGA complex regulates its own activity by undergoing multimerization. This multimerization is triggered by SAGA autoacetylation at three sites on its Ada3 subunit, allowing recognition of this acetylation by the bromodomain of the Gcn5/Spt7 SAGA subunit. Once multimerized, SAGA is capable of cooperatively acetylating chromatin, and an inability to autoacetylate Ada3 leads to transcriptional and phenotypic defects in a wide range of stress-activated genes. The SAGA multimerization increased significantly in media with Sucorse as the only carbon resource than that with Glucose. In this study, the high-throughput sequence of wild type (WT) strain, Ada3 acetylation mutant (Ada3-3KR), Gcn5 bromodomain mutant (Gcn5m) and Spt7 bromodomain mutant (Spt7m) indicate a new function for Ada3 acetylation, show which genes transcription can be regulated by SAGA multimers.

Project description:TFIID and SAGA share a common set of TAFs, regulate chromatin, and deliver TBP to promoters. Here we examine their relationship within the context of the Saccharomyces cerevisiae genome-wide regulatory network. We find that while TFIID and SAGA make overlapping contributions to the expression of all genes, TFIID function predominates at ~90% and SAGA at ~10% of the measurable genome. Strikingly, SAGA-dominated genes are largely stress-induced and TAF-independent, and are down-regulated by the coordinate action of a variety of chromatin, TBP, and RNA polymerase II regulators. In contrast, the TFIID-dominated class is less regulated, but is highly dependent upon TAFs including those shared between TFIID and SAGA. These two distinct modes of transcription regulation might reflect the need to balance inducible stress responses with the steady output of housekeeping genes. Keywords = Taf1 Keywords = Spt3 Keywords = Gcn5

Project description:Evidence indicates that transcription and mRNA export are linked processes. The molecular mechanisms of this coordination are not clear however. Sus1 (hENY2) participates in this coordination as part of two protein complexes: SAGA, a transcriptional co-activator and TREX-2 that functions in mRNA biogenesis and export. Here we investigate the coordinated action of SAGA and TREX-2 that is required for gene expression. We demonstrate that the TREX-2/proteasomal subunit Sem1, influences Sus1 role in mRNA export and TREX-2 stability. Wide analyses of gene expression reveal that Sem1 and Sus1 have also overlapping functions in transcription. In the absence of Sem1, expression of some SAGA-dependent genes is compromised with a concomitant decrease of RNAP II recruitment to promoters. Notably, ChIP experiments revealed a distinct dependency for SAGA subunits recruitment on Sem1. While absence of Sem1 lowers Ada2 and Taf9 recruitment to GAL1 promoter upon activation, association of the deubiquitylation module remains intact. However, H2B deubiquitylation activity is dramatically decreased. These results unveil a new role for Sem1 in influencing activation of SAGA-dependent H2B deubiquitylation likely mediated by stabilization of TREX-2 complex and SAGA modular assembly. Our work gives insights in how modular architecture of SAGA is determinant for its function in gene expression.