Project description:Antisense-mediated repression of SAGA-dependent genes involves the HIR histone chaperone

Project description:Pervasive transcription generates mainly unstable non-coding transcripts. Although a few examples of pervasive antisense have been shown to mediate gene regulation by transcriptional interference, whether pervasive transcription has a general functional role or merely represents transcriptional noise remains to be determined. In a mutant context that revealed pervasive transcripts, we characterized more than 800 antisenses genome wide and analysed the corresponding sense mRNA behaviour. We observed that antisense non-coding transcription is commonly found associated with genes tightly repressed during the exponential phase with an opposite level of mRNA and the associated antisense. This suggested that antisense transcription might participate to a tight repression of genes during the exponential phase. We thus specifically interrupted the antisense transcription of a subset of genes, and found that it resulted in a de-repression of the corresponding mRNAs. We further validated that this repression acts in cis through a transcriptional interference mechanism, which involves several chromatin modification factors. Transcription interference is observed for the first time as a general mean of gene regulation between cellular states.

Project description:Eukaryotic genomes are almost entirely scanned by RNA polymerase II (RNAPII). Consequently, the transcription of long noncoding RNAs (lncRNAs) often overlaps with coding gene promoters triggering potential gene repression through a poorly characterized mechanism of transcription interference. In this study, we propose a global model of chromatin-based transcription interference in Saccharomyces cerevisiae (S. cerevisiae). By using a noncoding transcription inducible strain, we analyzed the relationship between antisense elongation and coding sense repression, nucleosome occupancy and transcription-associated histone modifications using near-base pair resolution techniques. We show that antisense noncoding transcription leads to -1/+1 nucleosome deacetylation via H3K36 trimethylation (H3K36me3). This results in the loss of -1/+1 nucleosome interaction with the RSC chromatin remodeler and subsequent sliding into the Nucleosome-Depleted Region (NDR) hindering Pre-Initiation Complex (PIC) binding. Finally, we extend our model by showing that natural antisense noncoding transcription significantly regulates around 20% of S. cerevisiae genes through this chromatin-based transcription interference mechanism.

Project description:Recent studies have revealed that eukaryotic genomes are pervasively transcribed by RNA polymerase II, producing a plethora of non-coding RNAs which frequently overlap protein-coding genes. Despite the fact that overlapping transcription is well known to repress transcription initiation from downstream promoters, the mechanism behind this phenomenon has remained elusive. It was proposed that transcriptional interference relies on the act of transcription rather than the RNA itself to block access of the transcription machinery to downstream promoters. Here, we use the fission yeast Schizosaccharomyces pombe to demonstrate that an RNA and chromatin-dependent mechanism is responsible for transcriptional interference. This relies on co-transcriptional recruitment of the histone deacetylase Clr3 to nascent non-coding RNA, leading to formation of hypoacetylated chromatin and repression of the downstream protein-coding gene. Our findings highlight the unexpected requirement for RNA as well as trans-acting protein factors in mediating the repressive effects imposed on gene expression through overlapping non-coding transcription.

Project description:Recent studies have revealed that eukaryotic genomes are pervasively transcribed by RNA polymerase II, producing a plethora of non-coding RNAs which frequently overlap protein-coding genes. Despite the fact that overlapping transcription is well known to repress transcription initiation from downstream promoters, the mechanism behind this phenomenon has remained elusive. It was proposed that transcriptional interference relies on the act of transcription rather than the RNA itself to block access of the transcription machinery to downstream promoters. Here, we use the fission yeast Schizosaccharomyces pombe to demonstrate that an RNA and chromatin-dependent mechanism is responsible for transcriptional interference. This relies on co-transcriptional recruitment of the histone deacetylase Clr3 to nascent non-coding RNA, leading to formation of hypoacetylated chromatin and repression of the downstream protein-coding gene. Our findings highlight the unexpected requirement for RNA as well as trans-acting protein factors in mediating the repressive effects imposed on gene expression through overlapping non-coding transcription.

Project description:Recent studies have revealed that eukaryotic genomes are pervasively transcribed by RNA polymerase II, producing a plethora of non-coding RNAs which frequently overlap protein-coding genes. Despite the fact that overlapping transcription is well known to repress transcription initiation from downstream promoters, the mechanism behind this phenomenon has remained elusive. It was proposed that transcriptional interference relies on the act of transcription rather than the RNA itself to block access of the transcription machinery to downstream promoters. Here, we demonstrate that an RNA and chromatin-dependent mechanism is responsible for transcriptional interference in fission yeast. This relies on co-transcriptional recruitment of the histone deacetylase Clr3 to nascent non-coding RNA, leading to formation of hypoacetylated chromatin and repression of the downstream protein-coding gene. Our findings highlight the unexpected requirement for RNA as well as trans-acting protein factors in mediating the repressive effects imposed on gene expression through overlapping non-coding transcription.

Project description:TFIID and SAGA complexes play a critical role in RNA Polymerase II dependent activated transcription. Although the two regulatory complexes are recruited to promoters by activation domain-interactions, the contribution of the different subunits or the different domains of the individual subunits is not completely understood. Taf9 is a shared subunit in TFIID and SAGA and has an N-terminal H3-like histone fold domain and a highly conserved C-terminal domain, Taf9-CTD. In this study, we have uncovered an essential role for the Taf9-CTD in transcriptional activation. The Taf9-CTD was not essential for the histone-fold mediated interaction with Taf6, SAGA and TFIID integrity or Gcn4 interaction with SAGA. Transcriptome profiling performed under Gcn4 activating conditions showed that the Taf9-CTD is required for expression of ~17% of the yeast genome and provides a coactivator function to recruit TFIID and SAGA complexes to the promoters in vivo during transcriptional activation. Integrated genome-wide data analysis showed that the Taf9-CTD is required for activation of promoters bound by several transcription factors indicating a broad role for Taf9-CTD in promoter occupancy of TFIID or SAGA complexes. Interestingly, only a subset of the promoters seemed to be dependent on the Taf9-CTD for assembly of the pre-initiation complex indicating redundancy in activator targets to assemble PIC in vivo. Together these results indicate that evolutionarily conserved domains in shared subunits of TFIID and SAGA have a pervasive role in genome-wide transcription. This GEO series consists of 14 microarray hybridizations using the Agilent two-color experiment with the Agilent Custom Saccharomyces cerevisiae 8x15k gene expression array. Four biological replicates each for the wild-type (TAF9), the mutant taf9-tCRD2 strain treated or untreated with SM, and the wild-type (TAF9) versus mutant taf9-tCRD2 treated with SM hybridized as dye-swapped replicates. Two biological replicates for wild-type (SPT20) vs spt20D strains treated with SM, and hybridized as dye-swapped replicates to identify the fraction of SAGA dependent genes under amino-acid starvation conditions. The overall aim was to identify genes dependent on the conserved C-terminal region domain of TAF9 and determine their dependence on the SAGA subunit Spt20 for expression.

Project description:Antisense RNAs are non-coding RNAs, which can regulate their corresponding sense RNAs and are generally produced from specific promoters. By genome-wide approaches and in depth analyses at specific loci in human cells undergoing senescence, we uncover a family of antisense RNAs produced by transcriptional read-through at convergent protein-coding genes. Importantly, these antisense RNAs, that we named STARTs, repress the expression of their corresponding sense RNAs. We found that the elongation rate of RNA pol II is limited downstream of the TTS at START loci in proliferative cells. This allows transcription termination to occur before the RNA pol II reaches the convergent genes, thus preventing antisense RNA production and interference with the expression of the convergent genes. In proliferative cells, STARTs are repressed by the histone variant H2A.Z, whose local occupancy decreases in senescence. Our results thus uncover a novel mechanism of gene expression regulation, relying on the control of the expression of read-through antisense transcripts at convergent genes and underline the functional importance of the epigenetic control of RNA pol II elongation rate at intergenic regions.

Project description:Antisense RNAs are non-coding RNAs, which can regulate their corresponding sense RNAs and are generally produced from specific promoters. By genome-wide approaches and in depth analyses at specific loci in human cells undergoing senescence, we uncover a family of antisense RNAs produced by transcriptional read-through at convergent protein-coding genes. Importantly, these antisense RNAs, that we named STARTs, repress the expression of their corresponding sense RNAs. We found that the elongation rate of RNA pol II is limited downstream of the TTS at START loci in proliferative cells. This allows transcription termination to occur before the RNA pol II reaches the convergent genes, thus preventing antisense RNA production and interference with the expression of the convergent genes. In proliferative cells, STARTs are repressed by the histone variant H2A.Z, whose local occupancy decreases in senescence. Our results thus uncover a novel mechanism of gene expression regulation, relying on the control of the expression of read-through antisense transcripts at convergent genes and underline the functional importance of the epigenetic control of RNA pol II elongation rate at intergenic regions.

Project description:Antisense RNAs are non-coding RNAs, which can regulate their corresponding sense RNAs and are generally produced from specific promoters. By genome-wide approaches and in depth analyses at specific loci in human cells undergoing senescence, we uncover a family of antisense RNAs produced by transcriptional read-through at convergent protein-coding genes. Importantly, these antisense RNAs, that we named STARTs, repress the expression of their corresponding sense RNAs. We found that the elongation rate of RNA pol II is limited downstream of the TTS at START loci in proliferative cells. This allows transcription termination to occur before the RNA pol II reaches the convergent genes, thus preventing antisense RNA production and interference with the expression of the convergent genes. In proliferative cells, STARTs are repressed by the histone variant H2A.Z, whose local occupancy decreases in senescence. Our results thus uncover a novel mechanism of gene expression regulation, relying on the control of the expression of read-through antisense transcripts at convergent genes and underline the functional importance of the epigenetic control of RNA pol II elongation rate at intergenic regions.