Project description:Ribosomal DNA (rDNA) is organized as large arrays of tandem repeats that vary in copy number from a few dozen to hundreds. In the budding yeast Saccharomyces cerevisiae, each rDNA repeat includes a potential origin of replication. Previous work has led to the model that the rDNA replication origins compete for limiting replication initiation factors with origins in the rest of the genome, suggesting that reduction in rDNA copy number would reduce competition for these limiting factors and therefore promote origin usage in the rest of the genome. To test this hypothesis, we compared genome-wide replication in strains with either wild type rDNA copy number of ~180 (“180 rDNA”) or just ~35 copies (“35 rDNA”) by performing dense-to-light isotope transfer experiments to physically separate replicated, hybrid-density (HL or heavy-light) DNA from unreplicated, HH (heavy-heavy) DNA in cell samples collected at different times in S phase. Contrary to our expectations, we find that although there are no apparent differences in non-rDNA origin activity between the two strains, the 35 rDNA strain shows a genome-wide delay in progression through S phase compared to the 180 rDNA strain.

Project description:C. elegans rDNA copy number variant lines

Project description:In this study we perform ATAC-seq of budding yeast strains with variable copy number of the rRNA genes (rDNA CN). We aim to better understand the relationship between DNA accessibility and replicative lifespan in strains with variable rDNA CN.

Project description:To sustain growth, budding yeast actively transcribes its ribosomal gene array (rDNA) in the nucoleolus to produce ribosomes and proteins. However, intense transcription during rDNA replication may provoke collisions between RNA polymerase I (Pol I) and the replisome, may cause replication fork instability, double-strand breaks, local recombinations and rDNA instability. The latter is manifested by rDNA array expansion or reduction and the formation of extrachromosomal rDNA circles, anomalies that accelerate aging in yeast. Transcription also interferes with the resolution, condensation and segregation of the sister chromatid rDNA arrays. As a consequence, rDNA segregation lags behind the rest of the yeast genome and occurs in late anaphase when rDNA transcription is temporarily shut off. How yeast promotes the stability and transmission of its rDNA array while satisfying a constant need for ribosomes remains unclear. Here we show that the downregulation of Pol I by the conserved cell cycle kinase Rio1 spatiotemporally coordinates rDNA transcription, replication and segregation. More specifically, Rio1 activity promotes copy-number stability of the replicating rDNA array by curtailing Pol I activity and by localising the histone deacetylase Sir2, which establishes a heterochromatic state that silences rDNA transcription. At anaphase entry, Rio1 and the Cdc14 phosphatase target Pol I subunit Rpa43 to dissociate Pol I from the 35S rDNA promoter. The rDNA locus then condensates and segregates, thereby concluding the genome transmission process. Rio1 is involved in ribosome maturation in the cytoplasm of budding yeast and human cells. Additional engagements in the cytoplasm or roles in the nucleus are unknown. Our study describes its first nuclear engagement as a Pol I silencing kinase. This activity may prove highly relevant as dysregulated RNA polymerase I activity has been associated with cancer initiation and proliferation.

Project description:Transcription of the several hundred of mouse and human Ribosomal RNA (rRNA) genes accounts for the majority of RNA synthesis in the cell nucleus and is the determinant of cytoplasmic ribosome abundance, a key factor in regulating gene expression. The rRNA genes, referred to globally as the rDNA, are clustered as direct repeats at the Nucleolar Organiser Regions, NORs, of several chromosomes, and in many cells the active repeats are transcribed at near saturation levels. The rDNA is also a hotspot of recombination and chromosome breakage, and hence understanding its control has broad importance. Despite the need for a high level of rDNA transcription, typically only a fraction of the rDNA is transcriptionally active, and some NORs are permanently silenced by CpG methylation. Various chromatin-remodelling complexes have been implicated in counteracting silencing to maintain rDNA activity. However, the chromatin structure of the active rDNA fraction is still far from clear. Here we have combined a high-resolution ChIP-Seq protocol with conditional inactivation of key basal factors to better understand what determines active rDNA chromatin. The data resolve questions concerning the interdependence of the basal transcription factors, show that preinitiation complex formation is driven by the architectural factor UBF (UBTF) independently of transcription, and exclude a significant role for termination by a torpedomechanism. They further reveal the existence of an asymmetric Boundary Complex formed by CTCF, Cohesin and three phased nucleosomes lying adjacent to the rDNA Enhancer and an arrested RNA Polymerase I complex. We find that this complex is the only site of active histone modification in the whole 45kbp rDNA repeat. Strikingly, the Enhancer Boundary Complex not only delimits each functional rRNA gene, but also is stably maintained after gene inactivation and the re-establishment of surrounding repressive chromatin. Our data define the poised state of rDNA chromatin and place the Enhancer Boundary Complex as the likely entry point for the chromatin remodelling complexes.

Project description:In this study we perform RNA-seq of budding yeast strains with variable copy number of the rRNA genes (rDNA CN) to assess the relationship between rDNA CN and gene expression. RNA-seq was performed on samples both with and without polyA selection (for all transcripts and for rRNA transcripts, respectively).

Project description:Please see publication. These experiments were performed to ascertain the contribution of Y-linked rDNA copy number variation in the modulation of gene expression. Males (XY) and female (XXY) genotypes were probed.

Project description:Here we have RNA binding protein DDX18 connecting rRNA transcription to early embryo development and embryonic stem cell (ESC) identity maintenance. DDX18 mutant embryos suffer lethality during preimplantation development. DDX18 depletion impairs ESC self-renewal and pluripotency, which phenotype-copies RNA polymerase I (RNAPI) inhibition. Mechanistically, DDX18 is recruited to rDNA by RNAPI transcription machinery and senses rRNA transcription by binding to pre-rRNA. In nucleolus, DDX18 surrounds DFC ring and interacts with PRC2. In the presence of transcribed pre-rRNA, DDX18 interaction with PRC2 makes EZH2 unstably binding to the other components of PRC2, thereby preventing PRC2 engagement and counteracting H3K27me3 mediated silencing at rDNA chromatin. Together, our study shows that DDX18 plays important roles in safeguarding ESCs identity through regulating epigenetic states of rDNA locus and maintaining euchromatin structure in nucleolus.

Project description:The diet consumed by fathers prior to procreation impacts metabolic phenotypes in their offspring, but the mechanisms underlying such intergenerational information transfer remain obscure. Here, we carried out extensive analysis of cytosine methylation patterns in murine sperm, generating whole genome methylation maps for 4 pools of sperm samples and for 12 individual sperm samples, as well as 61 genome-scale reduced-representation bisulfite sequencing (RRBS) methylation maps, using samples obtained from male mice consuming various diets. We found that epivariation, either stochastic or due to unknown demographic or environmental factors, was a far stronger contributor to the sperm methylome than was the diet consumed. Variation in cytosine methylation was particularly dramatic over tandem repeat families, including ribosomal DNA (rDNA) repeats, and rDNA methylation levels were heritable from one generation to the next. However, rDNA methylation was strongly correlated with genetic variation in rDNA copy number, and analysis of hundreds of sperm samples revealed no consistent effect of diet on rDNA copy number or methylation level in sperm, indicating that paternal diet exerts an rDNA methylation-independent effect on offspring gene expression. These results reveal loci of genetic and epigenetic lability in the mammalian genome, but strongly argue against a direct mechanistic role for sperm cytosine methylation in dietary reprogramming of offspring metabolism.

Project description:HS-10502 is a Poly(ADP-ribose) polymerase 1 (PARP1)-specific selective inhibitor. The purpose if this study is to assess the safety, tolerability, pharmacokinetics (PK), and efficacy of HS-10502 in subjects with homologous recombination repair (HRR) gene mutant or homologous recombination deficiency (HRD) positive advanced solid tumors.