Browsing by Subject "R-loops"
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Item Open Access Guidelines for DNA recombination and repair studies: Cellular assays of DNA repair pathways.(Microbial cell (Graz, Austria), 2019-01-07) Klein, Hannah L; Bačinskaja, Giedrė; Che, Jun; Cheblal, Anais; Elango, Rajula; Epshtein, Anastasiya; Fitzgerald, Devon M; Gómez-González, Belén; Khan, Sharik R; Kumar, Sandeep; Leland, Bryan A; Marie, Léa; Mei, Qian; Miné-Hattab, Judith; Piotrowska, Alicja; Polleys, Erica J; Putnam, Christopher D; Radchenko, Elina A; Saada, Anissia Ait; Sakofsky, Cynthia J; Shim, Eun Yong; Stracy, Mathew; Xia, Jun; Yan, Zhenxin; Yin, Yi; Aguilera, Andrés; Argueso, Juan Lucas; Freudenreich, Catherine H; Gasser, Susan M; Gordenin, Dmitry A; Haber, James E; Ira, Grzegorz; Jinks-Robertson, Sue; King, Megan C; Kolodner, Richard D; Kuzminov, Andrei; Lambert, Sarah Ae; Lee, Sang Eun; Miller, Kyle M; Mirkin, Sergei M; Petes, Thomas D; Rosenberg, Susan M; Rothstein, Rodney; Symington, Lorraine S; Zawadzki, Pawel; Kim, Nayun; Lisby, Michael; Malkova, AnnaUnderstanding the plasticity of genomes has been greatly aided by assays for recombination, repair and mutagenesis. These assays have been developed in microbial systems that provide the advantages of genetic and molecular reporters that can readily be manipulated. Cellular assays comprise genetic, molecular, and cytological reporters. The assays are powerful tools but each comes with its particular advantages and limitations. Here the most commonly used assays are reviewed, discussed, and presented as the guidelines for future studies.Item Open Access Native Origins for Constitutive Stable DNA Replication in Escherichia Coli(2012) Maduike, Nkabuije ZikaodiConstitutive stable DNA replication (cSDR) is an alternative mode of replication initiation in Escherichia coli. cSDR is active in rnhA and recG mutants, which lack proteins that remove DNA-RNA hybrids called R-loops. The mechanism for cSDR initiation, therefore, is thought to involve these R-loop structures, which are proposed to form at specific locations known as oriK sites on the chromosome. Thus far, oriK sites have only been mapped to broad, 100-200 kb regions on the chromosome, so the specific elements involved in initiation are still unknown. My research focused on localizing the oriK sites on the chromosome, specifically those in the terminus region, where two of the major oriK sites had previously been mapped. We used two-dimensional gel electrophoresis (Friedman & Brewer, 1995) to analyze the replication forks that are blocked at the innermost Ter sites at the terminus, and found that elevated levels of replication forks are blocked at the Ter sites in rnhA mutants. We also used microarray and deep sequencing analysis to determine that there is a major location of oriK activity in the chromosome, located in the region between TerA and TerC. Furthermore, we also studied the use of the activation-induced deaminase (AID) enzyme as a tool for identifying regions of R-loop formation in the chromosome, and learned about its properties in the process.
Item Open Access Novel Understandings of How Cancer Prevents and Responds to DNA Damage(2020) Edwards, DrakeUnderstanding the differences between normal and malignant tissue is required to find vulnerabilities in cancer that can be exploited. One of the hallmarks of cancer is its ability to sustain proliferative signaling, leading to unbridled cellular replication. This puts an increased pressure on the cell’s ability to maintain genome integrity and creates a potential vulnerability to be targeted by cancer therapies. Targeting how a cancer cell prevents or responds to DNA damage is one way to take advantage of this vulnerability.
My dissertation work aims to better understand this DNA damage response in cancer and tests two hypotheses: The first is whether inhibition of the transcriptional regulator BRD4 leads to an increase in transcription-replication conflicts, DNA damage, and cell death. The second is whether the tumor microenvironment alters the way cancer cells respond to DNA damage induced by radiation therapy in glioblastoma.
Effective spatio-temporal control of transcription and replication during S-phase is paramount to maintain genomic integrity and cell survival. My work shows that BRD4, a BET bromodomain protein and known transcriptional regulator, is important for preventing dysregulation of these systems leading to conflicts between the transcription and replication machinery in S-phase. We demonstrate that inhibition or degradation of BET bromodomain proteins leads to an accumulation of RNA:DNA hybrids, a known cause of transcription-replication conflicts, and causes increased DNA damage and cell death in cancer cells actively undergoing replication. Furthermore,
over-expression of full-length BRD4, which contains a P-TEFb interacting domain known to activate efficient transcription, is necessary and sufficient to rescuing this effect. These results give mechanistic insight into chemotherapeutics that target BRD4 currently in clinical trials.
In complementary work, we explored the effect that the extracellular environment of cancer plays in its response to DNA damage caused by radiation therapy. Standard methods of culturing cancer cells, which do not replicate the extracellular environment of a native tumor, have led to an incomplete understanding of response to therapies such as ionizing radiation in vivo. To understand the role that the tumor environment plays on the radiation response, we used both human and murine glioblastoma cells to show that organotypic brain slice culture was better able to recapitulate the expression profiles of in vivo tumors. Specifically, we saw that pathways involved in multicellular processes, cell morphogenesis, and the extracellular matrix were not only significantly upregulated in glioblastoma cells cultured on brain slices compared to in vitro culture but were also critically important to radiation survival.
Collectively, this dissertation provides novel understandings of how cancer cells prevent and respond to DNA damage as well as a framework for future work in cancer biology.
Item Open Access Very high levels of misincorporated ribonucleotides increase Topoisomerase1 related genome alterations(2017-05-09) Zhang, LijiaA combination of high-resolution mapping of genomic rearrangements throughout the genome using microarrays, and measurements of loss of heterozygosity (LOH) on the right arm of chromosome IV were used to examine the effects of misincorporated ribonucleotides (rNMPs) on genome stability in diploid Saccharomyces cerevisiae strains. The effects of three types of mutations were examined in my analysis. Strains with a top1 mutation lack the Topoisomerase 1 enzyme, an enzyme that is involved in relaxing supercoils and in the removal of rNMPs from the genome. Strains with the rnh201 mutation lack RNase H2, an enzyme that removes both R-loops (RNA-DNA hybrids formed during transcription) and misincorporated rNMPs. Lastly, strains with the pol2-M644G mutation have a mutant form of DNA polymerase ε that misincorporates about 10-fold more rNMPs than the wild-type enzyme. My analysis of genetic instability in single mutants and various combinations of double and triple mutants shows that high levels of misincorporated rNMPs elevate mitotic recombination. Since mitotic recombination events are initiated in yeast by double-stranded DNA breaks (DSBs), my results suggest that high levels of misincorporated rNMPs result in elevated levels of DNA breaks.