Project description:The proposal aims to characterise the pathways of DSB repair and recombination in Arabidopsis with the main focus of this research being the NHEJ pathway of illegitimate recombination. We will build on our expertise and resources in the field of DSB repair in plants, using the Arabidopsis NHEJ mutant atku80 which is an excellent model system for the study of DSB repair in higher eukaryotes (West et al., 2002 Plant J. 31, 517-28). Comparison of the transcriptome in NHEJ mutant and wild type plants under different experimental conditions will identify novel candidate genes involved in DNA DSB repair or damage signalling pathways.We will conduct 4 separate experiments on Arabidopsis seedlings grown on 0.5 MS media: the first will be a control consisting of Wassilewskija (WS-2) plants grown under standard conditions. In the second experiment WS plants will be exposed to the chemotherapeutic agent bleomycin (1 microgram per ml). This agent has been shown to cause both single and double strand breaks in the genome of Arabidopsis seedlings (Menke et al., 2001 Mut. Res. 493, 87-93). This agent is used in preference to gamma irradiation, which causes high levels of oxidative damage to cellular components. These experiments will characterise for the first time the transcriptional responses of Arabidopsis cells to the specific induction of DNA strand breaks. The transcript profile will also be determined in untreated atku80 mutants. This experiment will identify the components of novel and previously characterised DNA repair pathways up regulated in the mutant background. Finally, transcript analysis of bleomycin treated atku80 mutants and comparison with untreated mutant plants and both untreated and treated WS plants will identify novel putative DSB repair genes up regulated in response to genotoxic stress in the absence of a Ku80 mediated DSB repair pathway.The results of these studies will provide new and important information which will be instrumental in identifying novel genes and pathways involved in DNA repair and genome stability in plants and help elucidate the fundamental differences that exist between animal and plant DSB repair processes. Experiment Overall Design: Number of plants pooled:20

Project description:The proposal aims to characterise the pathways of DSB repair and recombination in Arabidopsis with the main focus of this research being the NHEJ pathway of illegitimate recombination. We will build on our expertise and resources in the field of DSB repair in plants, using the Arabidopsis NHEJ mutant atku80 which is an excellent model system for the study of DSB repair in higher eukaryotes (West et al., 2002 Plant J. 31, 517-28). Comparison of the transcriptome in NHEJ mutant and wild type plants under different experimental conditions will identify novel candidate genes involved in DNA DSB repair or damage signalling pathways.We will conduct 4 separate experiments on Arabidopsis seedlings grown on 0.5 MS media: the first will be a control consisting of Wassilewskija (WS-2) plants grown under standard conditions. In the second experiment WS plants will be exposed to the chemotherapeutic agent bleomycin (1 microgram per ml). This agent has been shown to cause both single and double strand breaks in the genome of Arabidopsis seedlings (Menke et al., 2001 Mut. Res. 493, 87-93). This agent is used in preference to gamma irradiation, which causes high levels of oxidative damage to cellular components. These experiments will characterise for the first time the transcriptional responses of Arabidopsis cells to the specific induction of DNA strand breaks. The transcript profile will also be determined in untreated atku80 mutants. This experiment will identify the components of novel and previously characterised DNA repair pathways up regulated in the mutant background. Finally, transcript analysis of bleomycin treated atku80 mutants and comparison with untreated mutant plants and both untreated and treated WS plants will identify novel putative DSB repair genes up regulated in response to genotoxic stress in the absence of a Ku80 mediated DSB repair pathway.The results of these studies will provide new and important information which will be instrumental in identifying novel genes and pathways involved in DNA repair and genome stability in plants and help elucidate the fundamental differences that exist between animal and plant DSB repair processes. Keywords: strain_or_line_design; compound_treatment_design

Project description:We investigated how yeast cells deficient in performing homologous recombination-mediated DNA repair due to a deletion of the critical RAD52 gene respond to irreparable DNA damage inflicted by genotoxic treatment commonly applied in cancer therapy (camptothecin and irradiation). We found that upon persistence of irreparable DNA damage, yeast rad52 mutants readily undergo checkpoint adaptation accompanied by the acquisition of resistance to further genotoxic insults as well as the development of aneuploidy. Together, our findings can be used to elucidate how repair-defective cancer cells can become treatment-resistant thereby providing a way to target these resistant cell clones by tackling their aneuploidy-associated phenotypes. To investigate these characteristics commonly present in aneuploid cells in our experimental set-up, we treated yeast cells with genotoxic agents and performed whole genome sequencing. We could identify frequent whole chromosome loss events manifesting in a sensitivity of cells to aneuploidy-targeting agents.

Project description:Transcriptional profiling of human fibroblast cells after DNA damage with Camptothecin or Etoposide or Neocarzinostatin Upon DNA damage, the DNA damage response (DDR) elicits a complex signaling cascade, which includes the induction of multiple non-coding RNA species. Recently long non-coding RNAs (lncRNAs) have been shown to contribute to DDR by regulating gene expression. However, very little is known about the role that lncRNAs play in regulating DNA Repair. Using a genome-wide microarray screen we identified a novel ubiquitously expressed lncRNA, DDSR1 (DNA damage-sensitive RNA 1), which is induced upon DNA damage by several DNA double-strand break (DSB) agents. Two-condition experiment, Control vs. DNA damage human fibroblast cells. No Replicates, DNA damage was induced with either Camptothecin or Etoposide or Neocarzinostatin, Total RNA or Nuclear RNA was profiled.

Project description:DNA damage response and repair are key biological pathways to prevent genome instability caused by inefficient repair induced permanent mutations. Such changes may cause alterations to the normal cell cycle, the induction of apoptosis and the initiation and promotion of cancer development. Recently, the roles of ncRNAs functioning in the DNA damage response and DNA repair have gain more attention. To find out key ncRNAs involved in DNA damage response or repair pathways, we detected the transcription levels of ncRNAs in HeLa cells following ultraviolet (UV) light or methyl methanesulfonate (MMS) treatments by microarrays. This identified a variety of ncRNAs respond to UV or MMS-induced DNA damage. Therefore, further investigation on the ncRNAs in response to these genotoxic agents would help to provide a deeper understanding of the mechanism of ncRNAs functioning in the DNA damage response and repair pathways and new strategies of treatment of cancer by co-ordinately targeting ncRNA repair factors.

Project description:Maintaining genome integrity presents a particular challenge for plants due to their sedentary lifestyle, which disables direct avoidance of unfavorable external conditions. Additionally, plants’ metabolic processes generate reactive molecules as by-products of e.g. photosynthesis, creating internal DNA-damaging conditions. Due to this, plants have developed a unique and strictly regulated web of DNA damage responses (DDR). We initiated analysis of the DDR system in cultivated barley (Hordeum vulgare), a temperate cereal model with a large and repeat rich genome. A series of DNA damaging assays was established to describe barley plants’ phenotypic response to chemically induced DNA double-strand breaks. The efficacy of assays as a tool to be used for assessing potential new DDR barley mutants was demonstrated. DNA damage response network activation in barley was assessed by transcriptome analysis using RNA sequencing for wild type and mutant in the DDR signaling kinase ATAXIA TELANGIECTASIA MUTATED AND RAD3-RELATED (ATR). Considering the barley genome had only recently been sequenced, and it lacks the in-depth gene analysis, a list of potential DNA damage response genes in barley was compiled based on their homology with Arabidopsis genes. The comparison of transcripts in wild-type plants and atr mutants following genotoxic stress

Project description:In response to genotoxic stress the TP53 tumour suppressor activates target gene expression to induce cell cycle arrest or apoptosis depending on the extent of DNA damage. These canonical activities can be repressed by TP63 in normal stratifying epithelia to maintain proliferative capacity or drive proliferation of squamous cell carcinomas, where TP63 is frequently overexpressed/amplified. Here we use ChIP-sequencing, integrated with microarray analysis, to define the genome wide interplay between TP53 and TP63 in response to genotoxic stress in normal cells. We reveal that TP53 and TP63 bind to overlapping, but distinct cistromes of sites through utilization of distinctive consensus motifs and that TP53 is constitutively bound to a number of sites. We demonstrate that cisplatin and adriamycin elicit distinct effects on TP53 and TP63 binding events, through which TP53 can induce or repress transcription of an extensive network of genes by direct binding and/or modulation of TP63 activity. Collectively, this results in a global TP53 dependent repression of cell cycle progression, mitosis and DNA damage repair concomitant with activation of anti-proliferative and pro-apoptotic canonical target genes. Further analyses reveals that in the absence of genotoxic stress TP63 plays an important role in maintaining expression of DNA repair genes, loss of which results in defective repair Examination of p63 and p53 binding sites in neonatal foreskin keratinocytes in response to adriamycin or cisplatin treatment

Project description:Various modes of DNA repair counteract genotoxic DNA double-strand breaks (DSBs) to maintain genome stability. Recent findings suggest that the human DNA damage response (DDR) utilises damage-induced small RNA for efficient repair of DSBs. However, production and processing of RNA is poorly understood. Here we show that localised induction of DSBs triggers phosphorylation of RNA polymerase II (RNAPII) on carboxy-terminal domain (CTD) residue tyrosine-1 in an Mre11-Rad50-Nbs1 (MRN) complex-dependent manner. CTD Tyr1-phosphorylated RNAPII synthetises, strand-specific, damage-responsive transcripts (DARTs). DART synthesis occurs via formation of transient RNA-DNA hybrid (R-loop) intermediates. Impaired R-loop formation attenuates DART synthesis, impairs recruitment of repair factors and delays the DDR. Collectively, we provide mechanistic insight in RNA-dependent DSB repair.

Project description:Targetted metabolomics in U2OS PRDX1 WT and PRDX1-/- While cellular metabolism impacts the DNA damage response, a systematic understanding of the metabolic requirements that are crucial for DNA damage repair has yet to be achieved. Here, we investigate the metabolic enzymes and processes that are essential when cells are exposed to DNA damage. By integrating functional genomics with chromatin proteomics and metabolomics, we provide a detailed description of the interplay between cellular metabolism and the DNA damage response. Subsequent analysis identified Peroxiredoxin 1, PRDX1, as fundamental for DNA damage repair. During the DNA damage response, PRDX1 translocates to the nucleus where it is required to reduce DNA damage-induced nuclear reactive oxygen species levels. Moreover, PRDX1 controls aspartate availability, which is required for the DNA damage repair-induced upregulation of de novo nucleotide synthesis. Loss of PRDX1 leads to an impairment in the clearance of γΗ2ΑΧ nuclear foci, accumulation of replicative stress and cell proliferation defects, thus revealing a crucial role for PRDX1 as a DNA damage surveillance factor.

Project description:In double-strand DNA damage repair, non-homologous end joining (NHEJ) is more error prone than homologous recombination repair (HRR), indicating that the relative prevalence of NHEJ may lead to more incorrect repair and thus to increases in chromosome damage. If DNA damage is extensive and cells are unable to repair that damage they typically undergo apoptosis. The mechanism(s) by which cells decide to switch from DNA repair to apoptosis is unknown. Since DNA repair and apoptosis are both energy-demanding processes, the answer may involve ATP utilization. We used human mitochondrial mutant cell lines obtained from people with phenotypic manifestations of compromised ATP generation. We hypothesized that these cells may not have adequate capacity for dealing with the additional demands for ATP required for repairing DNA damage after genotoxic exposure, perhaps making the cells more prone to undergo apoptosis instead of initiating repair. This study describes changes in the expression of genes involved in NHEJ or HRR, as well as genes involved in apoptosis, in one normal and two mitochondrial mutant human cell lines following ionizing radiation exposure. Compared to normal cells, both mutant cell lines showed reduced expression of genes involved in NHEJ and HRR. Analysis of expression changes in genes involved in apoptosis revealed marked increases in expression in the mutants compared to normal cells. These results indicate that following ionizing radiation exposure, mitochondrial mutant cells have decreased levels of mRNA expression of DNA repair genes and increased expression levels of genes involved in apoptosis compared to normal cells. This study provides information that might be useful in characterizing energy dependent processes following exposure to stress or genotoxic agents.