Browsing by Subject "DNA repair"
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Item Open Access Acute Myeloid Leukemia After Olaparib Treatment in Metastatic Castration-Resistant Prostate Cancer.(Clinical genitourinary cancer, 2017-12) Zhu, Jason; Tucker, Matthew; Wang, Endi; Grossman, Joel S; Armstrong, Andrew J; George, Daniel J; Zhang, TianItem Open Access Genetic Control of Genomic Alterations Induced in Yeast by Interstitial Telomeric Sequences(2018) Moore, Anthony RTelomeric sequences are often located internally on the chromosome in addition to their usual positions at the ends of the chromosome. These internally-located telomeric sequences have been termed “interstitial telomeric sequences” (ITSs). In humans, ITSs are non-randomly associated with translocation breakpoints in tumor cells and with chromosome fragile sites (regions of the chromosome that break in response to perturbed DNA replication). We previously showed that ITSs in yeast stimulated point mutations in DNA sequences adjacent to the ITS as well as several types of chromosomal rearrangements. The major class of these rearrangements was the terminal inversion, which inverted the chromosome segment between the ITS and the “true” chromosome telomere. In the current study, we examined the genetic control of these events. We show that the terminal inversions likely occur by the formation of a double-stranded DNA break within the ITS, followed by repair of the break utilizing the single-strand annealing pathway. The point mutations induced by the ITS require the error-prone DNA polymerase zeta. Unlike the terminal inversions, these events are not initiated by a double-stranded DNA break, but likely result from error-prone repair of a single-stranded DNA gap or recruitment of DNA polymerase zeta in the absence of DNA damage.
Item Open Access Genetic variants of genes in the NER pathway associated with risk of breast cancer: A large-scale analysis of 14 published GWAS datasets in the DRIVE study.(International journal of cancer, 2019-09) Ge, Jie; Liu, Hongliang; Qian, Danwen; Wang, Xiaomeng; Moorman, Patricia G; Luo, Sheng; Hwang, Shelley; Wei, QingyiA recent hypothesis-free pathway-level analysis of genome-wide association study (GWAS) datasets suggested that the overall genetic variation measured by single nucleotide polymorphisms (SNPs) in the nucleotide excision repair (NER) pathway genes was associated with breast cancer (BC) risk, but no detailed SNP information was provided. To substantiate this finding, we performed a larger meta-analysis of 14 previously published GWAS datasets in the Discovery, Biology and Risk of Inherited Variants in Breast Cancer (DRIVE) study with 53,107 subjects of European descent. Using a hypothesis-driven approach, we selected 138 candidate genes from the NER pathway using the "Molecular Signatures Database (MsigDB)" and "PathCards". All SNPs were imputed using IMPUTE2 with the 1000 Genomes Project Phase 3. Logistic regression was used to estimate BC risk, and pooled ORs for each SNP were obtained from the meta-analysis using the false discovery rate for multiple test correction. RegulomeDB, HaploReg, SNPinfo and expression quantitative trait loci (eQTL) analysis were used to assess the SNP functionality. We identified four independent SNPs associated with BC risk, BIVM-ERCC5 rs1323697_C (OR = 1.06, 95% CI = 1.03-1.10), GTF2H4 rs1264308_T (OR = 0.93, 95% CI = 0.89-0.97), COPS2 rs141308737_C deletion (OR = 1.06, 95% CI = 1.03-1.09) and ELL rs1469412_C (OR = 0.93, 95% CI = 0.90-0.96). Their combined genetic score was also associated with BC risk (OR = 1.12, 95% CI = 1.08-1.16, ptrend < 0.0001). The eQTL analysis revealed that BIVM-ERCC5 rs1323697 C and ELL rs1469412 C alleles were correlated with increased mRNA expression levels of their genes in 373 lymphoblastoid cell lines (p = 0.022 and 2.67 × 10-22 , respectively). These SNPs might have roles in the BC etiology, likely through modulating their corresponding gene expression.Item Open Access Mapping of UV-Induced Mitotic Recombination in Yeast(2015) Yin, YiIn diploid yeast cells, mitotic recombination is very important for repairing double-strand breaks (DSB). When repair of a DSB results in crossovers, it may cause loss of heterozygosity (LOH) of markers centromere-distal to the DSB in both daughter cells. Gene conversion events unassociated with crossovers cause LOH for an interstitial section of a chromosome. Alternatively, DSBs can initiate break-induced replication (BIR), causing LOH in only one of the daughter cells. Mapping mitotic LOH contributes to understanding of mechanisms for repairing DSBs and distribution of these recombinogenic lesions. Methods for selecting mitotic crossovers and mapping the positions of crossovers have recently been developed in our lab. Our current approach uses a diploid yeast strain that is heterozygous for about 55,000 SNPs, and employs SNP-Microarrays to map LOH events throughout the genome. These methods allow us to examine selected crossovers on chromosome V and unselected mitotic recombination events (crossovers, gene conversion events unassociated with crossovers, and BIR events) at about 1 kb resolution across the genome.
Mitotic recombination can be greatly induced by UV radiation. However, prior to my research, the nature of the recombinogenic lesions and the distribution of UV-induced recombination events were relatively uncharacterized. Using SNP microarrays, we constructed maps of UV-induced LOH events in G1-synchronized cells. Mitotic crossovers were stimulated 1500-fold and 8500-fold by UV doses of 1 J/m2 and 15 J/m2, respectively, compared to spontaneous events. Additionally, cells treated with 15 J/m2 have about eight unselected LOH events per pair of sectors, including gene conversions associated and unassociated with crossovers as well as BIR events. These unselected LOH events are distributed randomly throughout the genome with no particular hotspots; however, the rDNA cluster was under-represented for the initiation of crossover and BIR events. Interestingly, we found that a high fraction of recombination events in cells treated with 15 J/m2 reflected repair of two sister chromatids broken at roughly the same position. In cells treated with 1 J/m2, most events reflect repair of a single broken sister chromatid (Chapter 2).
The primary pathway to remove pyrimidine dimers introduced by UV is the nucleotide excision repair (NER) pathway. In NER, the dimer is excised to generate a 30-nucleotide gap that can be replicated to form DSBs if not filled in before DNA replication. The NER gap can also be expanded by Exo1p to form single stranded gaps greater than one kilobase. Alternatively, in the absence of NER, unexcised dimers could result in blocks of DNA replication forks. Resolving the stalled replication fork could lead to recombinogenic breaks. In Chapter 3 and Chapter 4, we analyzed recombination events in strains defective in various steps of processing of UV-induced DNA damage, including exo1 and rad14 mutants.
In Chapter 3, I show that Exo1p-expanded NER gaps contribute to UV-induced recombination events. Interestingly, I also found that Exo1p is also required for the hotspot activity of a spontaneous crossover hotspot involving a pair of inverted Ty repeats. In addition to its role of expanding a nick to a long single-stranded gap, Exo1p is also a major player in DSB end resection. Therefore, I examined the gene conversion tract lengths in strains deleted for EXO1. I found that, although crossover-associated gene conversion tracts become shorter in the exo1 mutant as expected, noncrossover tract lengths remained unaffected. As a result, noncrossover tracts are longer than crossover tracts in the exo1 mutant while the opposite result was observed in the wild-type strains. I proposed models to rationalize this observation.
In Chapter 4, to investigate whether the substantial recombinogenic effect in UV in G1-synchronized cells requires NER, we mapped UV-induced LOH events in NER-deficient rad14 diploids treated with 1 J/m2. Mitotic recombination between homologs was greatly stimulated, which suggests that dimers themselves can also cause recombination without processing by NER. We further show that UV-induced inter-homolog recombination events (noncrossover, crossover and BIR) depend on the resolvase Mus81p, and are suppressed by Mms2p-mediated error-free post-replication repair pathway.
The research described in Chapters, 2, 3, and 4 are in the publications Yin and Petes (2013), Yin and Petes (2014), and Yin and Petes (2015), respectively.
Item Open Access Mitotic DNA Damage Responses in Drosophila Polyploid Rectal Papillar Cells(2021) Clay, Delisa EllenMitosis involves the faithful segregation of two identical copies of chromosomes into two daughter cells. This process is highly regulated to maintain genome integrity, as mis-segregation of partial or whole chromosomes can lead to genomic instability. Cells are constantly exposed to both endogenous and exogenous forms of DNA damage, which if left unattended to, can contribute to mitotic errors. Cells therefore possess DNA damage responses (DDRs) which involves enacting cell cycle checkpoints, DNA damage repair, and in cases of extreme damage – cell death or senescence.While several lines of investigation have identified key mechanisms of the DDR during interphase of the cell cycle, there are several key questions that remain with regards to how cells deal with damage that persists into mitosis. Further, there is currently a gap in knowledge on the mechanisms, timing, and conditions in which different aspects of the DDR are active and coordinated. In this dissertation, I will demonstrate how I implemented genetic and imaging tools using our laboratory’s previously established model system, Drosophila rectal papillar cells [hereafter papillar cells]. Using this model, I studied (1) mechanisms of the DDR during mitosis, (2) mechanisms that act in the absence of key DDR components, and (3) novel regulators and protein-protein interactions of the mitotic DDR. This body of work contributes to the growing knowledge of how cells tolerate DNA damage that persists into mitosis.
Item Open Access Post-translational Regulation of RPA32, ATM and Rad17 Controls the DNA Damage Response(2009) Feng, JunjieThe eukaryotic genome integrity is safeguarded by the DNA damage response, which is composed of a network of signal transduction pathways that upon genotoxic stresses, arrest cell cycle progression, motivate repair processes, or induce apoptosis or senescence when cells incur irreparable DNA damage. During this process, DNA damage-induced post-translational modifications, most notably protein phosphorylation, of a variety of DNA damage-responsive proteins has been shown to mediate the initiation, transduction and reception of the DNA damage signals, resulting in alterations of their stability, activities or subcellular localizations, ultimately leading to activation of various downstream effector pathways.
While a lot has been elucidated on the downstream events of the DNA damage response, little is known about how DNA damage is detected. Two still ongoing studies of this dissertation attempt to address this question. Our preliminary work on ATM indicates that serine 2546 is critical for its kinase activity. Substitution of this residue with phosphomimetic aspartate, but not nonphosphorylable alanine, abrogates the kinase activity of ATM and fails to rescue the checkpoint-deficient phenotype exhibited by the ATM-deficient cells, suggesting that removal of an inhibitory phospho group at S2546 might be required for the activation of ATM. In another study, we identified a novel DNA-damage responsive threonine residue (T622) in Rad17, which undergoes ATM/ATR-dependent phosphorylation in vitro and in vivo. Ectopic expression of a phosphodeficient mutant (T622A) of Rad17, but not its wild-type control, shows a pronounced defect in sustaining Chk1 phosphorylation and the corresponding G2/M checkpoint upon DNA damage, suggesting that phosphorylation at T622 might complement that on the two previously reported phosphorylation sites, S635 and S645, to mediate G2/M checkpoint activation while the latter is primarily responsible for intra-S phase checkpoint.
Although a large amount of knowledge has been accumulated about the initiation and activation process of the DNA damage response, how cells recover, the equally important flip side of the response, has remained poorly understood. We have found that in cells recovering from replication stress, RPA32 phosphorylation at ATM/ATR-responsive sites T21 and S33, which reportedly suppresses DNA replication and recruiting other checkpoint and repair proteins to the DNA lesions, is reversed by the serine/threonine protein phosphatase 2A (PP2A). Cells with a RPA32 persistent-phosphorylation mimic (T21D/S33D) exhibit normal checkpoint activation and re-enter the cell cycle normally after recovery, but display a pronounced defect in the repair of DNA breaks. These data indicate that PP2A-mediated RPA32 dephosphorylation may be a required event during the repair process in the DNA damage response.
In summary, these studies in this dissertation highlight the importance of reversible phosphorylation and dephosphorylation in the modulation of the DNA damage response. What's more, they also extend our knowledge and deepen our understanding of this process by revealing that dephosphorylation may positively regulate the activation of cell cycle checkpoints, which is seemingly dominated by protein phosphorylation upon DNA damage, that phosphorylation of certain checkpoint proteins at different sites may result in distinct consequences, and that dephosphorylation of some activated checkpoint/repair proteins may function as an important mechanism for cells to recover from the DNA damage response.
Item Open Access Single-cell microarray enables high-throughput evaluation of DNA double-strand breaks and DNA repair inhibitors.(Cell Cycle, 2013-03-15) Weingeist, David M; Ge, Jing; Wood, David K; Mutamba, James T; Huang, Qiuying; Rowland, Elizabeth A; Yaffe, Michael B; Floyd, Scott; Engelward, Bevin PA key modality of non-surgical cancer management is DNA damaging therapy that causes DNA double-strand breaks that are preferentially toxic to rapidly dividing cancer cells. Double-strand break repair capacity is recognized as an important mechanism in drug resistance and is therefore a potential target for adjuvant chemotherapy. Additionally, spontaneous and environmentally induced DSBs are known to promote cancer, making DSB evaluation important as a tool in epidemiology, clinical evaluation and in the development of novel pharmaceuticals. Currently available assays to detect double-strand breaks are limited in throughput and specificity and offer minimal information concerning the kinetics of repair. Here, we present the CometChip, a 96-well platform that enables assessment of double-strand break levels and repair capacity of multiple cell types and conditions in parallel and integrates with standard high-throughput screening and analysis technologies. We demonstrate the ability to detect multiple genetic deficiencies in double-strand break repair and evaluate a set of clinically relevant chemical inhibitors of one of the major double-strand break repair pathways, non-homologous end-joining. While other high-throughput repair assays measure residual damage or indirect markers of damage, the CometChip detects physical double-strand breaks, providing direct measurement of damage induction and repair capacity, which may be useful in developing and implementing treatment strategies with reduced side effects.Item Open Access The Mechanism of Mitotic Recombination in Yeast(2010) Lee, Phoebe S.A mitotically dividing cell regularly experiences DNA damage including double-stranded DNA breaks (DSBs). Homologous mitotic recombination is an important mechanism for the repair of DSBs, but inappropriate repair of DNA breaks can lead to genome instability. Despite more than 70 years of research, the mechanism of mitotic recombination is still not understood. By genetic and physical studies in the yeast Saccharomyces cerevisiae, I investigated the mechanism of reciprocal mitotic crossovers. Since spontaneous mitotic recombination events are very infrequent, I used a diploid strain that allowed for selection of cells that had the recombinant chromosomes expected for a reciprocal crossover (RCO). The diploid was also heterozygous for many single-nucleotide polymorphisms, allowing the accurate mapping of the recombination events.
I mapped spontaneous crossovers to a resolution of about 4 kb in a 120 kb region of chromosome V. This analysis is the first large-scale mapping of mitotic events performed in any organism. One region of elevated recombination was detected (a "hotspot") and the region near the centromere of chromosome V had low levels of recombination ("coldspot"). This analysis also demonstrated the crossovers were often associated with the non-reciprocal transfer of information between homologous chromosomes; such events are termed "gene conversions" and have been characterized in detail in the products of meiotic recombination. The amount of DNA transferred during mitotic gene conversion events was much greater than that observed for meiotic conversions, 12 kb and 2 kb, respectively. In addition, about 40% of the conversion events had patterns of marker segregation that are most simply explained as reflecting the repair of a chromosome that was broken in G1 of the cell cycle.
To confirm this unexpected conclusion, I examined the crossovers and gene conversion events induced by gamma irradiation in G1- and G2-arrested diploid yeast cells. The gene conversion patterns of G1-irradiated cells (but not G2-irradiated cells) mimic the conversion events associated with spontaneous reciprocal crossovers (RCOs), confirming my hypothesis that many spontaneous crossovers are initiated by a DSB on an unreplicated chromosome. In conclusion, my results have resulted in a new understanding of the properties of mitotic recombination within the context of cell cycle.
Item Open Access Topoisomerase 1 (Top1)-associated Genome Instability in Yeast: Effects of Persistent Cleavage Complexes or Increased Top1 Levels(2016) Sloan, Roketa ShanellTopoisomerase 1 (Top1), a Type IB topoisomerase, functions to relieve transcription- and replication-associated torsional stress in DNA. Top1 cleaves one strand of DNA, covalently associates with the 3’ end of the nick to form a Top1-cleavage complex (Top1cc), passes the intact strand through the nick and finally re-ligates the broken strand. The chemotherapeutic drug, Camptothecin, intercalates at a Top1cc and prevents the crucial re-ligation reaction that is mediated by Top1, resulting in the conversion of a nick to a toxic double-strand break during DNA replication or the accumulation of Top1cc. This mechanism of action preferentially targets rapidly dividing tumor cells, but can also affect non-tumor cells when patients undergo treatment. Additionally, Top1 is found to be elevated in numerous tumor tissues making it an attractive target for anticancer therapies. We investigated the effects of Top1 on genome stability, effects of persistent Top1-cleavage complexes and elevated Top1 levels, in Saccharomyces cerevisiae. We found that increased levels of the Top1cc resulted in a five- to ten-fold increase in reciprocal crossovers, three- to fifteen fold increase in mutagenesis and greatly increased instability within the rDNA and CUP1 tandem arrays. Increased Top1 levels resulted in a fifteen- to twenty-two fold increase in mutagenesis and increased instability in rDNA locus. These results have important implications for understanding the effects of CPT and elevated Top1 levels as a chemotherapeutic agent.