Project description:Purpose: Determine whether Cdk1 only regulates a specific subset of tDNAs, or whether Cdk1 has a more global impact on tDNA expression; Method: We study the expression of tRNA genes in WT cells and cdk1-as1 mutants during S phase by small-RNAseq; Result: We found that expression of at least 77% of all tDNAs is significantly downregulated in S-phase in the cdk1-as1 mutant compared with the WT strain; Conclussions: Cdk1 promotes transcription of the majority of tRNA genes during the cell cycle.

Project description:Particularly in the context of differentiation and development, the importance of three-dimensional chromatin architecture to gene regulatory mechanisms is becoming increasingly clear. The most ancient known mechanism of chromatin organization involves TFIIIC, a transcription factor (TF) that recruits RNA polymerase III (Pol III) for transcription of tRNA and other types of non-coding RNA genes. From yeast to mammals, TFIIIC binds to tRNA genes (tDNAs) and scattered “extra-TFIIIC” (ETC) loci and serves to tether these loci together as anchors of chromatin loops. TFIIIC activities are modulated by MAF, MYC, and other TF proteins that are still unidentified. Here we identify the ZSCAN5 TF family - including mammalian ZSCAN5B and its primate-specific paralogs - as proteins that occupy mammalian Pol III promoters and ETC sites. We show that ZSCAN5B binds with high specificity to a conserved subset of tDNA loci and other Pol III genes in human and mouse and that primate-specific ZSCAN5A and ZSCAN5D also bind Pol III genes, although ZSCAN5D preferentially localizes to MIR SINE- and LINE2-associated ETC sites. ZSCAN5 genes are expressed in proliferating cell populations and are cell-cycle regulated, and gene expression data suggested that they might cooperate to regulate basic cellular functions including mitotic progression. Consistent with this predicted role, ZSCAN5A knockdown led to increasing numbers of cells in mitotic cells and aneuploidy in cultured cells. Together these data implicate ZSCAN5 genes in regulation of Pol III gene transcription and nearby Pol II genes, ultimately influencing cell cycle progression and differentiation in a variety of tissues.

Project description:Particularly in the context of differentiation and development, the importance of three-dimensional chromatin architecture to gene regulatory mechanisms is becoming increasingly clear. The most ancient known mechanism of chromatin organization involves TFIIIC, a transcription factor (TF) that recruits RNA polymerase III (Pol III) for transcription of tRNA and other types of non-coding RNA genes. From yeast to mammals, TFIIIC binds to tRNA genes (tDNAs) and scattered “extra-TFIIIC” (ETC) loci and serves to tether these loci together as anchors of chromatin loops. TFIIIC activities are modulated by MAF, MYC, and other TF proteins that are still unidentified. Here we identify the ZSCAN5 TF family - including mammalian ZSCAN5B and its primate-specific paralogs - as proteins that occupy mammalian Pol III promoters and ETC sites. We show that ZSCAN5B binds with high specificity to a conserved subset of tDNA loci and other Pol III genes in human and mouse and that primate-specific ZSCAN5A and ZSCAN5D also bind Pol III genes, although ZSCAN5D preferentially localizes to MIR SINE- and LINE2-associated ETC sites. ZSCAN5 genes are expressed in proliferating cell populations and are cell-cycle regulated, and gene expression data suggested that they might cooperate to regulate basic cellular functions including mitotic progression. Consistent with this predicted role, ZSCAN5A knockdown led to increasing numbers of cells in mitotic cells and aneuploidy in cultured cells. Together these data implicate ZSCAN5 genes in regulation of Pol III gene transcription and nearby Pol II genes, ultimately influencing cell cycle progression and differentiation in a variety of tissues.

Project description:Particularly in the context of differentiation and development, the importance of three-dimensional chromatin architecture to gene regulatory mechanisms is becoming increasingly clear. The most ancient known mechanism of chromatin organization involves TFIIIC, a transcription factor (TF) that recruits RNA polymerase III (Pol III) for transcription of tRNA and other types of non-coding RNA genes. From yeast to mammals, TFIIIC binds to tRNA genes (tDNAs) and scattered “extra-TFIIIC” (ETC) loci and serves to tether these loci together as anchors of chromatin loops. TFIIIC activities are modulated by MAF, MYC, and other TF proteins that are still unidentified. Here we identify the ZSCAN5 TF family - including mammalian ZSCAN5B and its primate-specific paralogs - as proteins that occupy mammalian Pol III promoters and ETC sites. We show that ZSCAN5B binds with high specificity to a conserved subset of tDNA loci and other Pol III genes in human and mouse and that primate-specific ZSCAN5A and ZSCAN5D also bind Pol III genes, although ZSCAN5D preferentially localizes to MIR SINE- and LINE2-associated ETC sites. ZSCAN5 genes are expressed in proliferating cell populations and are cell-cycle regulated, and gene expression data suggested that they might cooperate to regulate basic cellular functions including mitotic progression. Consistent with this predicted role, ZSCAN5A knockdown led to increasing numbers of cells in mitotic cells and aneuploidy in cultured cells. Together these data implicate ZSCAN5 genes in regulation of Pol III gene transcription and nearby Pol II genes, ultimately influencing cell cycle progression and differentiation in a variety of tissues.

Project description:The cell cycle is thought to be initiated by cyclin-dependent kinases (Cdk) inactivating transcriptional inhibitors of cell cycle gene-expression. In budding yeast, the G1 cyclin Cln3-Cdk1 complex is thought to directly phosphorylate Whi5, thereby releasing the transcription factor SBF and committing cells to division. Here, we report that Cln3-Cdk1 does not phosphorylate Whi5, but instead phosphorylates the RNA Polymerase II subunit Rpb1’s C-terminal domain (CTD) on S5 of its heptapeptide repeats. Cln3-Cdk1 binds SBF-regulated promoters(8) and Cln3’s function can be performed by the canonical S5 kinase Ccl1-Kin28 when synthetically recruited to SBF. Thus, Cln3-Cdk1 triggers cell division by phosphorylating Rpb1 at SBF-regulated promoters to promote transcription. Our findings blur the distinction between cell cycle and transcriptional Cdks to highlight the ancient relationship between these processes.

Project description:Folding of the mammalian genome is governed by architectural proteins, such asCTCF. TFIIIC, a RNA polymerase III transcription factor, has been identified as aninsulator but its role in genome topology is totally unknown. Here, we show that TFIIICestablishes long-range genomic interactions that affect gene expression. Upon serumstarvation (SS), TFIIIC occupancy increases at Alu elements (AEs) near promoters ofcell cycle-related genes. Bound AEs become H3K18 hyper-acetylated and fold tocontact distal pre-loaded CTCF sites near other cell cycle genes. The promoters ofthese genes also become hyper-acetylated ensuring their basal transcription during SSand their increased expression during serum re-exposure. Ablation of TFIIIC ordeletion of the TFIIIC-bound AE that loops to the G2/M cycling F (CCNF) locus affectsits expression and nuclear positioning. These results illustrate a novel function ofhuman TFIIIC in changing 3D genome topology through the epigenetic state of AEs.

Project description:Transcription of tRNA genes by RNA Polymerase III (RNAPIII) is tuned by signaling cascades. The emerging notion of differential tRNA gene regulation implies the existence of additional regulatory mechanisms. However, tRNA gene-specific regulators have not been described. Decoding the proteome of a native tRNA gene in yeast revealed reprogramming of the RNAPIII transcription machinery upon nutrient perturbation. Among the dynamic proteins, we identified Fpt1, a protein of unknown function that uniquely occupied RNAPIII regulated genes. Fpt1 binding at tRNA genes correlated with the efficiency of RNAPIII eviction upon nutrient perturbation and required the transcription factors TFIIIB and TFIIIC but not RNAPIII. In the absence of Fpt1, eviction of RNAPIII was reduced and the shutdown of ribosome biogenesis genes was impaired upon nutrient perturbation. Our findings provide support for a chromatin-associated mechanism required for RNAPIII eviction from tRNA genes and for tuning the physiological response to changing metabolic demands.

Project description:Eukaryotic chromosomes reach their stable rod-shaped appearance in mitosis in a reaction dependent on the evolutionarily conserved condensin complex. Little is known about how and where condensin associates with chromosomes. Here, we analyse condensin binding to budding yeast chromosomes using high resolution oligonucleotide tiling arrays. Condensin binding sites coincide with those of the loading factor Scc2/4 of the related cohesin complex. The sites map to tRNA genes, ribosomal protein genes, and other places characterised by the RNA polymerase III transcription factor TFIIIC. An ectopic B-Box element, recognised by TFIIIC, constitutes a minimal condensin binding site, and TFIIIC and the Scc2/4 complex promote productive condensin association with chromosomes. A similar pattern of condensin binding is conserved along fission yeast chromosomes. This reveals that TFIIIC binding sites, including tRNA genes, constitute a hitherto unknown chromosomal feature with important implications for chromosome architecture during both interphase and mitosis. Keywords: Chip-chip, cell type comparison

Project description:RNA polymerase III (RNAP III) synthetizes small essential non-coding RNA molecules such as tRNAs and 5S rRNA. In yeast and vertebrates, RNAP III needs general transcription factors TFIIIA, TFIIIB and TFIIIC to initiate transcription. TFIIIC, composed of six subunits, binds to internal promoter elements in RNAP III-dependent genes. Limited information is available about RNAP III transcription in the trypanosomatid protozoa Trypanosoma brucei and Leishmania major, which diverged early from the eukaryotic lineage. Analyses of the first draft of the trypanosomatid genome sequences failed to recognize orthologs of any of the TFIIIC subunits, suggesting that this transcription factor is absent in these parasites. However, a single putative TFIIIC subunit was recently annotated in the databases. Here we characterize this subunit in T. brucei and L. major and demonstrate that it corresponds to Tau95. In silico analyses showed that both proteins possess the typical Tau95 sequences: the DNA binding region and the dimerization domain. As anticipated for a transcription factor, Tau95 localized to the nucleus in insect forms of both parasites. Chromatin immunoprecipitation (ChIP) assays demonstrated that Tau95 binds to tRNA and U2 snRNA genes in T. brucei. Remarkably, by performing tandem affinity purifications we identified orthologs of TFIIIC subunits Tau55, Tau131 and Tau138 in T. brucei and L. major. Thus, contrary to what was assumed, trypanosomatid parasites do possess a TFIIIC complex. Other putative interacting partners of Tau95 were identified in T. brucei and L. major.

Project description:Loss of nutrient supply elicits alterations of the SUMO proteome and sumoylation is crucial to various cellular processes including transcription. However, the physiological significance of sumoylation of transcriptional regulators is unclear. To begin clarifying this, we mapped the SUMO proteome under nitrogen-limiting conditions in Saccharomyces cerevisiae. Interestingly, several RNA polymerase III (RNAPIII) components are major SUMO targets under normal growth conditions, including Rpc53, Rpc82, and Ret1, and nutrient starvation results in rapid desumoylation of these proteins. These findings are supported by ChIP-seq experiments that show that SUMO is highly enriched at tDNA genes. Furthermore, RNA-seq experiments revealed that preventing sumoylation results in significantly decreased tRNA transcription. TORC1 inhibition resulted in the same effect, and our data indicate that the SUMO and TORC1 pathways are both required for robust tDNA expression. Importantly, tRNA transcription was strongly reduced in cells expressing a non-sumoylatable Rpc82-4KR mutant, which correlated with a misassembled RNAPIII transcriptional complex. Our data suggest that in addition to TORC1 activity, sumoylation of RNAPIII is key to reaching full translational capacity under optimal growth conditions.