Characterization of the DNA Damage Resistance Gene RTT107

Roberts, Tania

28 July 2008

In Saccharomyces cerevisiae, RTT107 (ESC4, YHR154W) encodes a BRCT-domain protein that is important for recovery from DNA damage during S phase. I have found that Rtt107 forms a complex with the Slx1/Slx4 structure-specific nuclease. Deletion of SLX4 confers many of the same phenotypes observed in rtt107∆, including DNA damage sensitivity, prolonged DNA damage checkpoint activation, and increased spontaneous DNA damage, suggesting that Slx4 and Rtt107 function in concert. These defects are not shared by Slx1 indicating that the function of Slx4 and Slx1 in the DNA damage response is not entirely overlapping. Furthermore, I found that Slx4 regulates the phosphorylation of Rtt107 by the checkpoint kinase Mec1. The phenotypes conferred by deletion of RTT107 and the spectrum of its synthetic genetic interactions indicates that Rtt107 may function at stalled replication forks. I have shown that Rtt107 is recruited to chromatin in the presence of DNA damaging agents that cause DNA replication forks to stall. Recruitment of Rtt107 to chromatin requires Rtt109, an acetyltransferase, and the cullin Rtt101, but is not dependent on Slx4 or the checkpoint kinases. Rtt109 acetylates histone H3 on lysine 56 (H3-K56), yet recruitment of Rtt107 to chromatin does not require acetylation of H3-K56, indicating that Rtt109 may have additional targets. Chromatin immunoprecipitation indicates that the sites of Rtt107 binding correspond to regions at or near stalled replication forks throughout the genome. I propose that Rtt107 acts in the recovery from DNA damage by localizing to stalled replication forks and acting as a scaffold for assembly of DNA damage response proteins, ultimately promoting replication fork restart.

DNA damage response

487

Characterization of the DNA Damage Resistance Gene RTT107

Roberts, Tania

28 July 2008

In Saccharomyces cerevisiae, RTT107 (ESC4, YHR154W) encodes a BRCT-domain protein that is important for recovery from DNA damage during S phase. I have found that Rtt107 forms a complex with the Slx1/Slx4 structure-specific nuclease. Deletion of SLX4 confers many of the same phenotypes observed in rtt107∆, including DNA damage sensitivity, prolonged DNA damage checkpoint activation, and increased spontaneous DNA damage, suggesting that Slx4 and Rtt107 function in concert. These defects are not shared by Slx1 indicating that the function of Slx4 and Slx1 in the DNA damage response is not entirely overlapping. Furthermore, I found that Slx4 regulates the phosphorylation of Rtt107 by the checkpoint kinase Mec1. The phenotypes conferred by deletion of RTT107 and the spectrum of its synthetic genetic interactions indicates that Rtt107 may function at stalled replication forks. I have shown that Rtt107 is recruited to chromatin in the presence of DNA damaging agents that cause DNA replication forks to stall. Recruitment of Rtt107 to chromatin requires Rtt109, an acetyltransferase, and the cullin Rtt101, but is not dependent on Slx4 or the checkpoint kinases. Rtt109 acetylates histone H3 on lysine 56 (H3-K56), yet recruitment of Rtt107 to chromatin does not require acetylation of H3-K56, indicating that Rtt109 may have additional targets. Chromatin immunoprecipitation indicates that the sites of Rtt107 binding correspond to regions at or near stalled replication forks throughout the genome. I propose that Rtt107 acts in the recovery from DNA damage by localizing to stalled replication forks and acting as a scaffold for assembly of DNA damage response proteins, ultimately promoting replication fork restart.

DNA damage response

487

The interaction between Rad9 and Tousled-like kinase 1 in the cell cycle and the DNA damage response

Kelly, Ryan

24 December 2013

Genomic integrity is preserved by checkpoints, which are signal transduction pathways that serve to delay cell cycle progression in the presence of DNA damage or replication stress. The heterotrimeric Rad9-Rad1-Hus1 (9-1-1) complex is a proliferating cell nuclear antigen (PCNA)-like clamp that is loaded onto DNA at structures resulting from damage, and is important for initiating and maintaining checkpoint signaling. Rad9 possesses a C-terminal tail unrelated to PCNA that is phosphorylated constitutively and in response to cell cycle position and DNA damage. Previous studies have identified tousled-like kinase 1 (TLK1) as a kinase that may modify Rad9. This thesis establishes that Rad9 is indeed phosphorylated in a TLK-dependent manner in vitro and in vivo, and that T355 within the C-terminal tail is the primary targeted residue. Phosphorylation of Rad9 at T355 is quickly reduced upon exposure to ionizing radiation before returning to baseline later in the damage response. In addition, TLK1 and Rad9 were shown to interact constitutively, and this interaction is enhanced in chromatin-bound Rad9 at later stages of the damage response. Furthermore, this thesis demonstrates that TLK1 is required for progression through S-phase in normally cycling cells, and that depletion of TLK1 results in a prolonged G2/M arrest upon exposure to ionizing radiation, a phenotype that is mimicked by over-expression of a Rad9-T355A mutant. Given that TLK1 is transiently inactivated upon phosphorylation by Chk1 in response to DNA damage, this work proposes that TLK1 and Chk1 act in concert to modulate the phosphorylation status of Rad9, which in turn plays a role in regulating the DNA damage response. / Thesis (Ph.D, Biochemistry) -- Queen's University, 2013-12-24 10:31:57.987

cancer biology

DNA damage response

Conserved and Unconventional Responses to DNA Damage in Tetrahymena

Sandoval Oporto, Pamela

2011 May 1900

Here the ciliate protozoa Tetrahymena thermophila was used as a model system to study the DNA damage response. Tetrahymena enclose nuclear dimorphism, a polyploid somatic macronucleus (MAC), which is transcriptionally active and maintains vegetative growth, and a diploid germline micronucleus (MIC) responsible for the transmition of genetic information during conjugation. Previous studies have identified Tif1p, a novel protein involved in the regulation of rDNA replication in Tetrahymena. TIF1 hypomorphic strains acquire spontaneous DNA damage during vegetative cell cycle and are hypersensitive to DNA damaging agents. TIF1-deficient strains acquire DNA damage in both nuclear compartments, suggesting a global role of Tif1p in the maintenance of genomic stability. In my dissertation research, I studied the role of Tif1p during the cell cycle progression. To this end, I generated tagged-Tif1p strains, which revealed that the subcellular localization of Tif1p is dynamic throughout the cell cycle. However, the addition of epitope tag to this protein generated phenotypes analogous to ones observed in a TIF1-deficient strain. This suggested that the addition of epitope tag to Tif1p severely affects the properties of Tif1p and hence the overall integrity of the cell. To overcome these limitations, a peptide antibody specific to Tif1p was generated to study the endogenous protein. This work revealed that the abundance of Tif1p protein is not cell cycle regulated and that Tif1p is absent in starved cells. Furthermore, the specific binding of TIf1p to rDNA minichromosome was studied during vegetative cell cycles. Chromatin immunoprecipitation studies revealed that the specific binding of Tif1p extends beyond the cis-acting determinant of replication present at the rDNA origin and promoter. This suggests that coding regions may be targeted for the binding of Tif1p to previously uncharacterized sequences, and that Tif1p preferentially localizes on the rDNA minichromosome. I also studied the induction of DNA damage response, demonstrating that Tetrahymena activates a checkpoint response mediated by an ATR-like pathway. Studies with a hypomorphic TIF1 strain revealed that Tif1p mediates proper activation of the DNA damage response. Further characterization of the response to genotoxic agents showed that Tetrahymena is able to activate a G1/S and intra-S phase DNA damage response. The results presented here suggest that a caffeine-dependent checkpoint activator protein modulates the response to DNA damage. In addition, a subunit of the replicative helicase, Mcm6p, is directly affected by the induction of DNA damage. This suggests that Tetrahymena uses a novel mechanism to halt the progression of DNA replication forks during genotoxic stress through degradation of Mcm6p.

Tetrahymena

DNA damage response

Mcm6p

Constitutive activation of the ATM DNA damage response pathway in cancer represents a deregulated pathway

Din, Shahida

January 2014

Constitutive activation of the ATM dependent DNA damage response and repair pathways have been reported in pre-malignant and malignant human tissues and may undermine the efficacy of genotoxic cancer therapies. Therefore, ATM inhibitors may overcome resistance to current cytotoxics and potentiate the effects of radiotherapy. A colorectal cancer model was investigated to develop a framework for the rational use of ATM inhibitors. HCT116 p21-/- cells display constitutive activation of the ATM DNA damage response but display a defect in the ionising radiation induced S-phase checkpoint, termed radioresistant DNA synthesis. This radioresistant phenotype is associated with increased basal levels of Cdc25A protein, deficient DNA damage-induced degradation of Cdc25A and Chk2 mis-localisation. HCT116 p21-/- and SW620 cells, which exhibit basal Chk2 threonine-68 phosphorylation, were unable to abrogate the S-phase checkpoint when treated with an ATM inhibitor, suggesting that the ATM– Chk2 arm is non-functional in these cells: inhibition of ATM did not potentiate the efficacy of ionising irradiation. To assess activation of the pathway a tumour microarray was created using 179 treatment naïve sporadic colorectal cancers; 152 were of the microsatellite stable phenotype. Phosphorylated Chk2 threonine-68 was present in 22 % of microsatellite-stable colorectal tumours and 33 % of tumours with the microsatellite instability phenotype. In a colorectal cancer cell line model constitutive activation of the ATM DDR pathway reflected an attenuated ATM-Chk2 axis and inhibition of ATM in these circumstances was unable to potentiate the efficacy of ionising irradiation. Basal Chk2 threonine-68 phosphorylation may reflect a deregulated ATM DNA damage response pathway and/or checkpoint adaption and therefore use of an ATM inhibitor in this background may have limited efficacy. A predictive model is proposed that integrates functionality of the ATM-Chk2 axis, p53 mutation status and defects in DNA repair pathways when considering ATM inhibitor therapy. Ultimately, molecular phenotyping and functional analysis of processes deregulated in cancer will permit individualisation of current treatment modalities, improving their efficacy and limiting patient toxicity.

616.99

Characterisation of checkpoint kinase 1 and 2 in ovarian cancer

Francis, Kyle Evan

January 2016

CHEK1 inhibitors are currently in clinical trials for their ability to abrogate chemotherapy-induced CHEK1 activation and S phase arrest resulting in cancer cell apoptosis. No studies have yet identified ovarian cancers that could benefit from CHEK1-targeting therapy. I hypothesised that knowledge of CHEK1 and CHEK2 signalling in the DNA damage response can assist in identifying potential biomarkers for platinum responsiveness and CHEK-targeting therapy in ovarian cancer. In vitro studies investigated the CHEK1/2 inhibitor AZD7762 (AZD) and cisplatin (CP) in same patient-derived platinum-sensitive/resistant high-grade serous ovarian cancer cell lines (PEO1/PEO4 and PEO14/PEO23). Cytotoxicity assays confirmed higher CP IC50’s for PEO4 and PEO23 relative to PEO1 and PEO14 cell lines, respectively. AZD was more toxic to PEO1 cells and an additive effect of AZD with CP relative to CP alone was seen. A nontoxic AZD treatment to PEO4 cells sensitised the cells to CP when applied in combination. PEO14 and PEO23 cells had similar cytotoxicity profiles for combination treatments. BRDU DNA synthesis assays and cell cycle analysis revealed increased BRDU incorporation and accumulation in S phase when all cell lines were treated with CP. AZD treatment had a similar effect in PEO14 and PEO23 cells and increased the sub-G1 population, a marker of apoptotic DNA fragmentation, relative to control. Drug combination had no major effect on cell cycle distributions of both PEO14 and PEO23 cells relative to single agents but resulted in BRDU incorporation levels below CP and control levels for PEO14 cells. In PEO1 and PEO4 cells, AZD did not affect the cell cycle or DNA synthesis levels relative to control. Drug combination did not alter the cell cycle relative to CP treatment for PEO1 cells but decreased S phase and increased G2/M and sub-G1 populations in PEO4 cells. This was coupled with a decrease of CP-induced BRDU levels in PEO4 control levels. Apoptotic PARP cleavage/total PARP occurred early in CP treated PEO1 and PEO14 cells. A surrogate CHEK1/2 activity marker, p-CDC2 (Y15), decreased in all lines treated with AZD relative to control. Within PEO1 and PEO4 cells, greatest PARP cleavage was observed with combination treatment and coincided with high p-H2AX (S139), a DNA damage marker. p-CHEK1 (S317) and p-CHEK2 (T68), both ATR and ATM phosphorylation sites during DNA damage, increased for lone drug treatment and, to a greater extent, the combination drug treatments. PARP cleavage occurs across all treatments in PEO1 cells while it only occurs in the combination treatment for PEO4 cells. The latter coincides with a decrease in p-CHEK1 (S296) a CHEK1 autophosphorylation site, p-TP53 (S15), and p-BRCA1 (S1524), a homologous recombination marker, relative to the CP treated sample. In PEO14 and PEO23 cells, lone AZD and combination treatments had similar cleaved PARP/total PARP levels compared to the PEO14 CP treated cells. This was coupled with increased p-H2AX (S139), decreased CHEK1, and decreased CHEK2 autophosphorylation p-CHEK2 (S516). A human ovarian cancer xenograft model identified increases in p-H2AX (S139), CHEK1, p-CHEK1 (S317), p-CHEK2 (T68), and p-BRCA1 (S1524) in the carboplatin responsive cancers. In the paired pre- and post-chemotherapy human ovarian cancer samples, p-CHEK1 (S317) was elevated in post-chemotherapy responsive samples. In the first cohort, high p-CHEK1 (S317) was an independent poor overall survival biomarker and correlated with high p-H2AX (S139), MYC, p-CHEK1 (S296), p-CHEK2 (T68), p-CHEK2 (S516), and p-TP53 (S15). p-CHEK1 (S317) was associated with poor overall survival in serous ovarian cancers within the second pre-treatment ovarian cancer cohort. In conclusion, AZD can induce apoptosis in CP resistant cancer cells by synergising with CP to abrogate the S phase checkpoint, increase DNA damage, and inhibit CHEK1, and BRCA1 function. As a single agent, AZD can induce apoptosis by decreasing CHEK1 levels and CHEK2 activity. p- CHEK1 (S317) is a platinum responsive / poor prognostic biomarker.

APOBEC3B promotes genomic instability in myeloma cells / APOBEC3Bは骨髄腫細胞においてゲノム不安定性を促進する

Yamazaki, Hiroyuki

23 September 2020

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第22736号 / 医博第4654号 / 新制||医||1046(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 小川 誠司, 教授 武藤 学, 教授 滝田 順子 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Myeloma

APOBEC3B

oncogenesis

DNA damage response

490

Analysis of telomere maintenance in artemis defective human cell lines

Yasaei, Hemad

January 2009

Telomeres are physical ends of chromosomes consisting of (TTAGGG)n DNA sequence and a specialized set of proteins that protect chromosomal ends from degradation and from eliciting DNA damage response. These specialized set of proteins, known as shelterin, directly bind to telomeric DNA. In addition, some DNA double-strand break (DSB) repair proteins such as, DNA-PKcs and KU70/80, play active roles in telomere maintenance. Mouse knock-out experiments have revealed that deletion of either DNA-PKcs or Ku70/80 resulted in elevated levels of telomeric fusion, indicative of dysfunctional telomeres. Artemis protein is involved in DNA DSB repair through non-homologous end joining (NHEJ) and it is phosphorylated by DNAPKcs. Human cells defective in Artemis have been identified and shown to be radiosensitive and patients with an Artemis defective gene suffer from radiosensitive severe-combined immune deficiency syndrome (RS-SCID). Mouse cells defective in Artemis have elevated levels of telomeric fusion. We have demonstrated in this thesis that Artemis defective human cell lines show a mild telomeric dysfunction phenotype detectable at the cytological level. The nature of telomere dysfunction phenotype appears to be similar to that observed in DNAPKcs defective cells as exemplified by the presence of IR induced chromatid telomeric fusions. We have also shown that (a) DNA damage occurring within the telomeric DNA is difficult to repair or irreparable in older cells and that (b) Artemis defective older cells show higher proportion of DNA damage at telomeres than their normal counterparts. Finally, we have demonstrated that inhibition of DNA-PKcs causes (a) an increase in telomeric fusions in Artemis defective cell lines relative to both normal cell lines after inhibition and Artemis cell lines before inhibition and (b)elevated levels of DNA damage at telomeres following exposure of cells to radiation relative to both irradiated normal cells exposed to a DNA-PKcs inhibitor and irradiated Artemis defective cells but not exposed to the DNA-PKcs inhibitor. These results suggest that the effects of Artemis and DNA-PKcs on telomeres are cumulative. We have also performed (a) experiments to examine telomere function in Artemis defective cell lines after knocking down DNA-PKcs levels by RNAi and b) preliminary experiments to knock-down Artemis in DNA-PKcs defective cells. Taken together, our results suggest that the Artemis defect causes mild telomere dysfunction phenotype in human cells.

572.8

A mechanistic investigation into candidate markers of telomere-induced senescence in normal human epidermal keratinocytes

dos Santos Soares Martins de Castro, Alicia Maria

January 2014

Telomere dysfunction is one mechanism of cellular and tissue ageing. Dysfunctional telomeres in fibroblasts are recognised as DNA double-strand breaks (DSBs) and trigger the DNA damage pathway of senescence. However, telomere uncapping in normal human epidermal keratinocytes, via expression of the dominant negative mutant of the telomere repeat-binding factor 2 (TRF2!B!M), resulted in a senescent-like arrest without a significant DNA damage response (DDR). This suggests that either keratinocytes are unusually sensitive to telomere uncapping and the low DDR is sufficient to induce senescence or that dysfunctional telomeres may also be signalled through an alternative pathway. Subsequent analysis revealed genes HIST2H2BE, ICEBERG, S100A7 and HOPX as potential markers for telomere dysfunction-induced senescence (TDIS) since they were induced by telomere uncapping and seemed to be regulated by telomerase. The aim of this project was to assess the specificity of these candidate markers for TDIS and to select the most promising for use as a biomarker. To this end, keratinocytes were exposed to doses of ionising radiation, capable of generating transient or permanent damage to the DNA, or transduced with retroviral constructs expressing p14ARF, p16INK4a, p53 or TRF2!B!M and the gene expression levels of the candidates assessed after a recovery period or at the early stages of senescence. Whilst S100A7, HOPX or ICEBERG were not induced by a transient or persistent DDR or by p16INK4a, ICEBERG and HOPX were induced by p53 and p14ARF when these were ectopically expressed at higher levels. Thus, S100A7 seems to be the most specific early marker for telomere dysfunction in keratinocytes since it was selectively induced by telomere uncapping via expression of TRF2!B!M and not by DSBs or by over expression of p14ARF, p53 or p16INK4a. S100A7 may have the potential to identify cells with telomere dysfunction in human epithelia and body fluids.

572.8

The role of the DNA damage and repair pathways in the efficacy of oncolytic adenovirus for ovarian cancer

Tookman, Laura

January 2016

Defects within the DNA damage response (DDR) pathways are common in human malignancies. This is especially true in high-grade serous ovarian cancer (HGSOC) where defects within the Homologous Recombination (HR) pathway may be present in up to 50% of tumours. Oncolytic adenovirus is a potential novel therapy for human malignancies. These viruses infect malignant cells and multiply selectively within them causing cell death and release of mature virions. Here, I have investigated the role of the DDR in determining the efficacy of the E1A-CR2 deleted adenovirus type 5 (Ad5) vector, dl922-947, in ovarian cancer. I show that infection with dl922-947 stimulates a robust DDR within the host cell, which the virus manipulates in order to ensure optimal viral replication. In a panel of HGSOC cell lines, the extent of overreplication of genomic DNA and the degree of genomic damage following infection with dl922-947 was shown to correlate closely with viral efficacy. Functional HR, however, promoted viral DNA replication and augmented overall anti-cancer efficacy. Mechanistically, both BRCA2 and RAD51 localised to viral replication centres within the infected cell nucleus. RAD51 co-localisation was also demonstrated in cells with defective HR and occurred independently of BRCA2. In addition, a direct interaction was identified between RAD51 and adenovirus E2 DNA binding protein. Using functional assays of HR competence, I show that Ad5 infection does not alter cellular ability to repair DNA double-strand break damage via HR. These data suggest that oncolytic adenoviral therapy may be most clinically relevant in tumours with intact HR function. Using a high-throughput siRNA DNA repair screen, potential novel targets have been identified that can increase the efficacy of dl922-947 (for example: NONO) and also result in increased resistance (RPA). These results highlight the complex interplay between adenovirus and host cell. Further understanding of these pathways is vital to increase efficacy, develop biomarkers and improve patient selection into clinical trials for these therapies.