Project description:Heterochromatin comprises tightly compacted repetitive regions of eukaryotic chromosomes. The inheritance of heterochromatin through mitosis requires RNA interference (RNAi), which guides histone modification during the DNA replication phase of the cell cycle. Here, we show that the alternating arrangement of origins of replication and non-coding RNA in pericentromeric heterochromatin results in competition between transcription and replication. Co-transcriptional RNAi releases RNA polymerase II (PolII), allowing completion of DNA replication by the leading strand DNA polymerase, and associated histone modifying enzymes which spread heterochromatin with the replication fork. In the absence of RNAi, stalled forks are repaired by homologous recombination without histone modification. small RNA cloning from wild type and dcr1-deleted strains

Project description:Heterochromatin comprises tightly compacted repetitive regions of eukaryotic chromosomes. The inheritance of heterochromatin through mitosis requires RNA interference (RNAi), which guides histone modification 1 during the DNA replication phase of the cell cycle2. Here, we show that the alternating arrangement of origins of replication and non-coding RNA in pericentromeric heterochromatin results in competition between transcription and replication. Co-transcriptional RNAi releases RNA polymerase II (PolII), allowing completion of DNA replication by the leading strand DNA polymerase, and associated histone modifying enzymes3 which spread heterochromatin with the replication fork. In the absence of RNAi, stalled forks are repaired by homologous recombination without histone modification. RNA PolII ChIP from wild type and dcr1-deleted samples in exponentially growing and HU-arrested cultures.

Project description:The replication of eukaryotic genomes is highly regulated to ensure faithful transmission of all genetic information through cell divisions. In addition to stringent control of origin initiation by cell cycle controls and DNA damage checkpoints, spatial and temporal control of origins serves to stage and balance replication of different genomic regions, with potential implications for development and genome stability. Replication of highly repetitive sequences creates stressful competition between genomic regions for sufficient replication resources. Here, we examined histone deacetylases Rpd3 and Sir2 in balancing replication between unique sequences and the multi-copy ribosomal DNA gene cluster(s), which has emerged as an evolutionarily conserved node of genomic instability. We elucidate Rpd3's mechanism of origin regulation, which is distinct and independent of Sir2.

Project description:The replication of eukaryotic genomes is highly regulated to ensure faithful transmission of all genetic information through cell divisions. In addition to stringent control of origin initiation by cell cycle controls and DNA damage checkpoints, spatial and temporal control of origins serves to stage and balance replication of different genomic regions, with potential implications for development and genome stability. Replication of highly repetitive sequences creates stressful competition between genomic regions for sufficient replication resources. Here, we examined histone deacetylases Rpd3 and Sir2 in balancing replication between unique sequences and the multi-copy ribosomal DNA gene cluster(s), which has emerged as an evolutionarily conserved node of genomic instability. We elucidate Rpd3's mechanism of origin regulation, which is distinct and independent of Sir2.

Project description:Heterochromatin comprises tightly compacted repetitive regions of eukaryotic chromosomes. The inheritance of heterochromatin through mitosis requires RNA interference (RNAi), which guides histone modification during the DNA replication phase of the cell cycle. Here, we show that the alternating arrangement of origins of replication and non-coding RNA in pericentromeric heterochromatin results in competition between transcription and replication. Co-transcriptional RNAi releases RNA polymerase II (PolII), allowing completion of DNA replication by the leading strand DNA polymerase, and associated histone modifying enzymes which spread heterochromatin with the replication fork. In the absence of RNAi, stalled forks are repaired by homologous recombination without histone modification.

Project description:Heterochromatin comprises tightly compacted repetitive regions of eukaryotic chromosomes. The inheritance of heterochromatin through mitosis requires RNA interference (RNAi), which guides histone modification 1 during the DNA replication phase of the cell cycle2. Here, we show that the alternating arrangement of origins of replication and non-coding RNA in pericentromeric heterochromatin results in competition between transcription and replication. Co-transcriptional RNAi releases RNA polymerase II (PolII), allowing completion of DNA replication by the leading strand DNA polymerase, and associated histone modifying enzymes3 which spread heterochromatin with the replication fork. In the absence of RNAi, stalled forks are repaired by homologous recombination without histone modification.

Project description:SIR2 Suppresses Replication Gaps and Genome Instability in Yeast by Balancing Replication Between Repetitive and Unique Sequences

Project description:DNA replicates once per cell cycle. Interfering with the regulation of DNA replication initiation generates genome instability through over-replication and has been linked to early stages of cancer development. Here, we engineered genetic systems in budding yeast to induce unscheduled replication in the G1-phase of the cell cycle. Unscheduled G1 replication initiated at canonical S-phase origins. We quantified the composition of replisomes in G1- and S-phase and identified firing factors, polymerase alpha, and histone supply as factors that limit replication outside S-phase. G1 replication per se did not trigger cellular checkpoints. Subsequent replication during S-phase, however, resulted in over-replication and led to chromosome breaks and chromosome-wide, strand-biased occurrence of RPA-bound single-stranded DNA indicating head-to-tail replication collisions as a key mechanism generating genome instability upon G1 replication. Low-level, sporadic induction of G1 replication induced an identical response, indicating findings from synthetic systems are applicable to naturally occurring scenarios of unscheduled replication initiation.

Project description:In S. cerevisiae, replication timing is controlled by epigenetic mechanisms restricting the accessibility of origins to limiting initiation factors. About 30% of these origins are located within repetitive DNA sequences such as the ribosomal DNA (rDNA) array, but their regulation is poorly understood. Here, we have investigated how histone deacetylases (HDACs) control the replication program in budding yeast. This analysis revealed that two HDACs, Rpd3 and Sir2, control replication timing in an opposite manner. Whereas Rpd3 delays initiation at late origins, Sir2 is required for the timely activation of early origins. Moreover, Sir2 represses initiation at rDNA origins whereas Rpd3 counteracts this effect. Remarkably, deletion of SIR2 restored normal replication in rpd3 cells by reactivating rDNA origins. Together, these data indicate that HDACs control the replication timing program in budding yeast by modulating the ability of repeated origins to compete with single-copy origins for limiting initiation factors. BrdU-IP-chip analysis of origin usage in different yeast HDAC mutants

Project description:The finished human genome-assemblies comprise several hundred un-sequenced euchromatic gaps, which may be rich in long polypurine/polypyrimidine stretches. Human chromosome 20 currently has three remaining un-sequenced gaps on its q-arm. All three gaps are within gene-dense regions, or overlap loci associated with human disorders, including one gap, which is at DLGAP4. In this study we sequenced, determined the complete sizes and assessed epigenetic landscapes of all three un-sequenced gaps on human chromosome 20 using a methodological approach involving Sanger sequencing, mate-pair paired-end high-throughput sequencing and chromatin and methylation analysis. We found histone H3K27me3 to be distributed across all three gaps in immortalized B-lymphocytes. We found five novel CpG islands in one gap to be highly hypermethylated in genomic DNA from both peripheral blood lymphocytes and human cerebellum. One of these CpG islands was differentially methylated and paternally hypermethylated. Furthermore, computational analyses predicted the presence of structured non-coding RNAs (ncRNAs) in all three chromosome 20 gaps. We verified expression for thirteen candidate ncRNAs, some of which showed tissue-specificity. Four ncRNAs expressed within the gap at DLGAP4 show elevated expression particularly in the human brain. Our data suggests that un-sequenced human genome gaps may comprise functional elements. Mate-pair paired end sequencing using genomic DNA from human translocation carriers having chromosomal rearrangments of chromosomes other than chromosome 20 and chromatin, DNA methylation analysis using human peripheral blood lymphocytes and/or human cerebellum tissue. Analysis done for three remaining human chromosome 20 un-sequenced gap regions.