53BP1 mediated recruitment of RASSF1A at ribosomal DNA breaks facilitates local ATM signal amplification

DNA lesions occur across the genome and constitute a threat to cell viability; however, damage at specific genomic loci has a disproportionally greater impact on the overall genome stability. The ribosomal RNA gene repeats (rDNA) are emerging fragile sites due to repetitive nature, clustering and high transcriptional activity. Recent progress in understanding how the rDNA damage response is organized has highlighted the key role of adaptor proteins in the response. Here we identify that the scaffold and tumor suppressor, RASSF1A is recruited at sites of damage and enriched at rDNA breaks. Employing targeted nucleolar DNA damage, we find that RASSF1A recruitment requires ATM activity and depends on 53BP1. At sites of damage RASSF1A facilitates local ATM signal establishment and rDNA break repair. RASSF1A silencing, a common epigenetic event during malignant transformation, results in persistent breaks, rDNA copy number alterations and decreased cell viability. Meta-analysis of a lung adenocarcinoma cohort showed that RASSF1A epigenetic silencing leads in rDNA copy number discrepancies. Overall, we present evidence that RASSF1A acts as a DNA repair factor and offer mechanistic insight in how the nucleolar DNA damage response is organized.

A minimal rDNA array replicates early, delays genome replication, and uncouples anaphase entry from S phase completion

ABSTRACTRibosomal DNA (rDNA) copy number varies widely among individuals in many species, but the phenotypic consequences of such copy number fluctuations remain largely unexplored. In the yeast Saccharomyces cerevisiae, each rDNA repeat contains an origin of replication. Previous studies have demonstrated that the yeast rDNA locus can be a significant competitor for replication resources, suggesting that rDNA copy number variation may affect timely completion of genome-wide replication. We hypothesized that reduction in rDNA copy number and thus rDNA replication origins would reduce competition from the rDNA locus and thereby improve non-rDNA genome replication. To test this hypothesis, we engineered yeast strains with short rDNA arrays of 35 copies, a minimal copy number that still maintains wild type level ribosome function. Contrary to our hypothesis, the minimal rDNA strain displayed classic replication defects: decreased plasmid maintenance, delayed completion of chromosomal replication, and increased sensitivity to replication stress agonists. Although a normal rDNA array replicates late in S phase, the minimal rDNA array initiated replication in early S phase, resulting in delayed replication across the non-rDNA portions of the genome. Moreover, we discovered that absence of the rDNA fork barrier protein Fob1p increased DNA damage sensitivity in strains with early replicating rDNA. We present evidence that this increased sensitivity may be due to compromised regulation of cyclin phosphatase Cdc14p and premature entry into anaphase. Our results indicate that precocious rDNA replication, rather than total number of rDNA origins, compromises replication of the genome. Taken together, we suggest that the rDNA’s large, late-replicating state is evolutionarily conserved to promote genome stability through timely genome replication and coordination of S phase completion with anaphase entry.

Gene dosage compensation of rRNA transcript levels in Arabidopsis thaliana lines with reduced ribosomal gene copy number

The 45S rRNA genes (rDNA) are amongst the largest repetitive elements in eukaryotic genomes. rDNA consists of tandem arrays of rRNA genes, many of which are transcriptionally silenced. Silent rDNA repeats may act as ‘back-up’ copies for ribosome biogenesis and have nuclear organization roles. Through Cas9-mediated genome editing in the Arabidopsis thaliana female gametophyte we reduced 45S rDNA copy number to a plateau of ∼10%. Two independent lines had rDNA copy numbers reduced by up to 90% at the T7 generation, named Low Copy Number (LCN) lines. Despite drastic reduction of rDNA copies, rRNA transcriptional rates and steady-state levels remained the same as wild type plants. Gene dosage compensation of rRNA transcript levels was associated with reduction of silencing histone marks at rDNA loci and altered Nucleolar Organiser Region 2 organization. While overall genome integrity of LCN lines appears unaffected, a chromosome segmental duplication occurred in one of the lines. Transcriptome analysis of LCN seedlings identified several shared dysregulated genes and pathways in both independent lines. Cas9 genome editing of rRNA repeats to generate LCN lines provides a powerful technique to elucidate rDNA dosage compensation mechanisms and impacts of low rDNA copy number on genome stability, development, and cellular processes.

A new method for determining ribosomal DNA copy number shows differences between Saccharomyces cerevisiae populations

Ribosomal DNA genes (rDNA) encode the major ribosomal RNAs (rRNA) and in eukaryotic genomes are typically present as one or more arrays of tandem repeats. Species have characteristic rDNA copy numbers, ranging from tens to thousands of copies, with the number thought to be redundant for rRNA production. However, the tandem rDNA repeats are prone to recombination-mediated changes in copy number, resulting in substantial intra-species copy number variation. There is growing evidence that these copy number differences can have phenotypic consequences. However, we lack a comprehensive understanding of what determines rDNA copy number, how it evolves, and what the consequences are, in part because of difficulties in quantifying copy number. Here, we developed a genomic sequence read approach that estimates rDNA copy number from the modal coverage of the rDNA and whole genome to help overcome limitations in quantifying copy number with existing mean coverage-based approaches. We validated our method using strains of the yeast Saccharomyces cerevisiae with previously-determined rDNA copy numbers, and then applied our pipeline to investigate rDNA copy number in a global sample of 788 yeast isolates. We found that wild yeast have a mean copy number of 92, consistent with what is reported for other fungi but much lower than in laboratory strains. We also show that different populations have different rDNA copy numbers. These differences can partially be explained by phylogeny, but other factors such as environment are also likely to contribute to population differences in copy number. Our results demonstrate the utility of the modal coverage method, and highlight the high level of rDNA copy number variation within and between populations.Author summaryThe ribosomal RNA gene repeats (rDNA) form large tandem repeat arrays in most eukaryote genomes. Their tandem arrangement makes the rDNA prone to copy number variation, and there is increasing evidence that this copy number variation has phenotypic consequences. However, difficulties in measuring rDNA copy number hamper investigation into rDNA copy number dynamics and their significance. Here we developed a novel bioinformatics method for measuring rDNA copy number from whole genome sequence data that is based on the modal sequence read coverage. We established parameters for optimal performance of the method and validated it using yeast strains of known rDNA copy numbers. We then applied the method to a dataset of almost 800 global yeast isolates and demonstrate that yeast populations have different rDNA copy numbers that partially correlate with phylogeny. Our work provides a simple and accurate method for determining rDNA copy number that leverages the growing number of whole genome datasets, and highlights the dynamic nature of rDNA copy number.

Age-dependent ribosomal DNA variations and their effect on cellular function in mammalian cells

The ribosomal RNA gene, which consists of tandem repetitive arrays (rDNA repeat), is one of the most unstable regions in the genome. The rDNA repeat in the budding yeast is known to become unstable as the cell ages. However, it is unclear how the rDNA repeat changes in ageing mammalian cells. Using quantitative analyses, we identified age-dependent alterations in rDNA copy number and levels of methylation in mice. The degree of methylation and copy number of rDNA from bone marrow cells of 2-year-old mice were increased by comparison to 4-week-old mice in two mouse strains, BALB/cA and C57BL/6. Moreover, the level of pre-rRNA transcripts was reduced in older BALB/cA mice. We also identified many sequence variations among the repeats with two mutations being unique to old mice. These sequences were conserved in budding yeast and equivalent mutations shortened the yeast chronological lifespan. Our findings suggest that rDNA is also fragile in mammalian cells and alterations within this region have a profound effect on cellular function.Author SummaryThe ribosomal RNA gene (rDNA) is one of the most unstable regions in the genome due to its tandem repetitive structure. rDNA copy number in the budding yeast increases and becomes unstable as the cell ages. It is speculated that the rDNA produces an “aging signal” inducing senescence and death. However, it is unclear how the rDNA repeat changes during the aging process in mammalian cells. In this study, we attempted to identify the age-dependent alteration of rDNA in mice. Using quantitative single cell analysis, we show that rDNA copy number increases in old mice bone marrow cells. By contrast, the level of ribosomal RNA production was reduced because of increased levels of DNA methylation that represses transcription. We also identified many sequence variations in the rDNA. Among them, three mutations were unique to old mice and two of them were found in the conserved region in budding yeast. We then established a yeast strain with the old mouse-specific mutations and found this shortened the lifespan of the cells. These findings suggest that rDNA is also fragile in mammalian cells and alteration to this region of the genome affects cellular senescence.

Copy numbers of 45S and 5S ribosomal DNA arrays lack meaningful correlation in humans

The ribosomal DNA genes are tandemly arrayed in most eukaryotes and exhibit vast copy number variation. There is growing interest in integrating this variation into genotype-phenotype associations. Here, we explored a possible association of rDNA copy number variation with autism spectrum disorder and found no difference between probands and unaffected siblings. However, rDNA copy number estimates from whole genome sequencing are error-prone, so we sought to use pulsed-field gel electrophoresis, a classic gold-standard method, to validate rDNA copy number genotypes. The electrophoresis approach is not readily applicable to the human 45S arrays due to their size and location on five separate chromosomes; however, it should accurately resolve copy numbers for the shorter 5S arrays that reside on a single chromosome. Previous studies reported tightly correlated, concerted copy number variation between the 45S and 5S arrays, which should enable the validation of 45S copy number estimates with CHEF-gel-verified 5S copy numbers. Here, we show that the previously reported strong concerted copy number variation is likely an artifact of variable data quality in the earlier published 1000 Genomes Project sequences. We failed to detect a meaningful correlation between 45S and 5S copy numbers in the large, high-coverage Simons Simplex Collection dataset as well as in the recent high-coverage 1000 Genomes Project sequences. Our findings illustrate the challenge of genotyping repetitive DNA regions accurately and call into question the accuracy of recently published studies of rDNA copy number variation in cancers and aging that relied on diverse publicly available resources for sequence data.

Comparative Studies on the Polymorphism and Copy Number Variation of mtSSU rDNA in Ciliates (Protista, Ciliophora): Implications for Phylogenetic, Environmental, and Ecological Research

While nuclear small subunit ribosomal DNA (nSSU rDNA) is the most commonly-used gene marker in studying phylogeny, ecology, abundance, and biodiversity of microbial eukaryotes, mitochondrial small subunit ribosomal DNA (mtSSU rDNA) provides an alternative. Recently, both copy number variation and sequence variation of nSSU rDNA have been demonstrated for diverse organisms, which can contribute to misinterpretation of microbiome data. Given this, we explore patterns for mtSSU rDNA among 13 selected ciliates (representing five classes), a major component of microbial eukaryotes, estimating copy number and sequence variation and comparing to that of nSSU rDNA. Our study reveals: (1) mtSSU rDNA copy number variation is substantially lower than that for nSSU rDNA; (2) mtSSU rDNA copy number ranges from 1.0 × 104 to 8.1 × 105; (3) a most common sequence of mtSSU rDNA is also found in each cell; (4) the sequence variation of mtSSU rDNA are mainly indels in poly A/T regions, and only half of species have sequence variation, which is fewer than that for nSSU rDNA; and (5) the polymorphisms between haplotypes of mtSSU rDNA would not influence the phylogenetic topology. Together, these data provide more insights into mtSSU rDNA as a powerful marker especially for microbial ecology studies.

Копийность рибосомной ДНК (рДНК) в геномах женщин как фактор успешности ЭКО и наличия осложнений беременности

Определено количество копий рибосомных повторов (рДНК) в геномах женщин с нормальной и осложненной беременностью, а также женщин, подвергшихся процедуре экстракорпорального оплодотворения (ЭКО). Кроме того, измеряли содержание GC-богатой рДНК в образцах внеклеточной ДНК (вкДНК), полученных от женщин с нормальной и осложненной беременностью. Показано, что геномы более половины женщин с патологией беременности содержали либо больше, либо меньше копий рДНК, чем у любой женщины из контрольной группы. Также обнаружено более высокое содержание рДНК во вкДНК пациенток с осложненной беременностью, что свидетельствует о наличии хронического процесса аномальной гибели клеток в группе женщин с патологией беременности. Можно сделать принципиальный вывод: поскольку беременность является тяжелой нагрузкой на организм женщины, для успешного вынашивания требуется сбалансированный биогенез рибосом. Женщины как с низкой, так и с очень высокой копийностью рДНК имеют более высокую вероятность повышенного уровня апоптоза и попадания в группу риска. Параметр «число копий рДНК в геноме женщины» может служить дополнительным прогностическим маркером потенциальных осложнений беременности у женщины. Женщины с низким или высоким количеством копий рибосомных генов в геноме нуждаются в более внимательном ведении беременности. Показатели количества копий рДНК в геномах женщин с неудачными попытками ЭКО были значимо ниже, чем в геномах двух остальных групп. Этот факт говорит о том, что копийность рДНК в геноме является одним из факторов, влияющих на успех процедуры ЭКО. Если индвивидуальное число копий рДНК в геноме женщины меньше, чем 330, высок риск неудачного ЭКО. Необходимы дальнейшие исследования данного вопроса. As pregnancy is a stressful load for a woman, any stress-resistance factor is relevant to it. According to recent reports, ribosomal gene copy number in the genome is associated with the individual stress-resistance. We determined copy numbers of ribosomal DNA (rDNA) in genomes of pregnant women with normal and complicated pregnancy, and women after in vitro fertilization (IVF) procedure. We also measured the contents of GC-rich rDNA in cell-free DNA (cfDNA) derived from normal controls and complicated pregnancy cases. We have shown that genomes of more than a half of DNA samples from women with pregnancy pathology harbor either more, or less rDNA copies than any woman from the control group. We also found higher rDNA contents in cfDNA isolated from complicated pregnancy cases suggesting the presence of a permanent cell death process in pathology cases. A principal conclusion can be made: women with low rDNA copy numbers and with very high numbers can have higher cell death rates and belong to the risk group. The parameter «rDNA copy number in woman’s genome» can be an additional prognostic marker for eventual pregnancy complications in the woman. The numbers of rDNA copies in the genomes of women with failed IVF attempts was significantly lower than in the genomes of patients with succesfull outcome, suggesting that rDNA copy number in the genome is one of the factors that affect the success of the IVF procedure. If the individual rDNA copy number is under 330, the risk of IVF failure is high. Further studies are warranted.