Broad spectrum detection of DNA damage by Repair Assisted Damage Detection (RADD)

Holton, Nathaniel W; Ebenstein, Yuval; Gassman, Natalie R.

doi:10.1016/j.dnarep.2018.04.007

Cited by 19 publications

(28 citation statements)

References 31 publications

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“…Based on the altered protein expression and localization of BER proteins in TNBC cells, we evaluated cells for variation in levels of basal DNA damage using the broad spectrum DNA damage assay, Repair Assisted Damage Detection (RADD) [30]. RADD uses bacterial DNA glycosylases to detect and excise abasic sites, oxidative base lesions, bulky DNA adducts, and thymine dimers (see Material and Methods).…”

Section: Resultsmentioning

confidence: 99%

“…Then the gaps in the DNA where the lesions were excised and any strand breaks occur are then tagged by Klenow polymerase with a Digoxigenin-11-dUTP. Damage sites are detected by immunofluorescence as described in the materials and methods [30]. RADD was applied to the TNBC cell panel, and the nuclear fluorescence intensity of basal DNA damage quantified (Fig 5, S3 Fig).…”

Section: Resultsmentioning

confidence: 99%

“…Cells were plated in 8-well chambered coverglass, fixed, and permeabilized using the same procedure as for immunofluorescence. The Repair Assisted Damage Detection (RADD) assay was performed as described previously with minor modifications [30]. After permeabilization, cells were incubated with uracil DNA glycosylase (UDG) to remove uracil (NEB #M0304S), formamidopyrimidine [Fapy]-DNA glycosylase (Fapy-DNA glycosylase NEB #M0240S) to remove Fapy lesions, T4 Pyrimidine dimer glycosylase (T4PDG NEB #M-308S) to remove pyrimidine dimer lesions, endonuclease IV (Endo IV NEB #M0304S) to process oxidative damage, AP sites and modifies 3’ phosphates to 3’ OH, and endonuclease VIII (Endo VIII NEB #M0299S) to remove damaged pyrimidines diluted in 1X Thermpol buffer and incubated at 37 degrees C for 1 hour.…”

Section: Methodsmentioning

confidence: 99%

“…Samples were then counterstained with Alexa Fluor goat anti-mouse 546 at 1:400 in 2% BSA in PBS for 45 min at room temperature and nuclei were stained as for immunofluorescence. Image analysis was performed as described previously [30]. MDA-231 cells were used to set the 546 nm laser gain, and the other cells were imaged at that gain.…”

Section: Methodsmentioning

confidence: 99%

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Defective base excision repair in the response to DNA damaging agents in triple negative breast cancer

Lee

Piett

Andrews

et al. 2019

Preprint

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21 22 23DNA repair defects have been increasingly focused on as therapeutic targets. In hormone 24 positive breast cancer, XRCC1-deficient tumors have been identified and proposed as 25 targets for combination therapies that damage DNA and inhibit DNA repair pathways. 26XRCC1 is a scaffold protein that functions in base excision repair (BER) by mediating 27 essential interactions between DNA glycosylases, AP endonuclease, poly(ADP-ribose) 28 polymerase 1, DNA polymerase β (POL β), and DNA ligases. Loss of XRCC1 confers 29 BER defects and hypersensitivity to DNA damaging agents. BER defects have not been 30 evaluated in triple negative breast cancer (TNBC), for which new therapeutic targets and 31 therapies are needed. To evaluate the potential of XRCC1 as an indicator of BER defects 32 in TNBC, we examined XRCC1 expression and localization in the TCGA database and in 33 TNBC cell lines. High XRCC1 expression was observed for TNBC tumors in the TCGA 34 database and expression of XRCC1 varied between TNBC cell lines. We also observed 35 changes in XRCC1 subcellular localization in TNBCs that alter the ability to repair base 36 lesions and single-strand breaks. Subcellular localization changes were also observed for 37 POL β that did not correlate with XRCC1 localization. Basal levels of DNA damage were 38 also measured in the TNBC cell lines, and damage levels correlated with observed 39 changes in XRCC1 expression, localization, and repair functions. The results confirmed 40 that XRCC1 expression changes may indicate DNA repair capacity changes but 41 emphasize that basal DNA damage levels along with expression and localization are 42 better indicators of DNA repair defects. Given the observed over-expression of XRCC1 in 43 TNBC preclinical models and the TCGA database, XRCC1 expression levels should be 44 considered when evaluating treatment responses of TNBC preclinical model cells. 45 3 Keywords: triple negative breast cancer, base excision repair, XRCC1, PARP1, DNA 46 repair, DNA damage, nuclear localization 47 48 Defects in DNA damage response and repair are driving factors in carcinogenesis 49and key determinants in the response to chemotherapy. Breast cancers may display 50 defects in DNA repair such as mutations in key DNA damage response and repair 51 proteins such as breast cancer-susceptibility (BRCA1/2) and tumor suppressor protein 52 p53 (TP53), and altered expression levels of DNA repair proteins thymine-DNA 53 glycosylase (TDG) and poly(ADP-ribose) polymerase 1 (PARP1) [1-3]. Therapeutic 54 outcomes may be improved by exploiting DNA repair defects present in cancer cells but 55 absent in normal cells, as in the use of PARP-inhibitors (PARPi) in cancers that have 56 BRCA1/2 deficiencies. However, characterization of DNA repair pathways often is lacking 57 in preclinical models and cell lines. Examining DNA repair defects in preclinical models 58 and patients is essential for evaluating the efficacy of therapeutic agents. 59 In breast cancer, DNA repair defects often extend beyond homologous 60 re...

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Defective base excision repair in the response to DNA damaging agents in triple negative breast cancer

Lee

Piett

Andrews

et al. 2019

Preprint

Self Cite

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“…While several biochemical and cell‐based tests of DNA repair capacity have been developed and shown to be reasonably objective and reliable, quantification of DNA repair capacity in humans remains unsatisfactory (Berwick & Vineis, ; Trzeciak et al, ; Trzeciak, Barnes, & Evans, ). The few tests described in the literature have not been applied to large populations and lack independent validation (El‐Zein et al, ; Fang, Neutzner, Turtschi, Flammer, & Mozaffarieh, ; Hamann & Hartwig, ; Holton, Ebenstein, & Gassman, ; Nagel et al, ; Reddy et al, ). Moreover, there is no consensus on gold standard assays and most methods require large amounts of freshly collected pure cell types, and these only address repair capacity of a subset of specific lesions.…”

Section: Introductionmentioning

confidence: 99%

Measuring biological aging in humans: A quest

et al. 2019

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The global population of individuals over the age of 65 is growing at an unprecedented rate and is expected to reach 1.6 billion by 2050. Most older individuals are affected by multiple chronic diseases, leading to complex drug treatments and increased risk of physical and cognitive disability. Improving or preserving the health and quality of life of these individuals is challenging due to a lack of well‐established clinical guidelines. Physicians are often forced to engage in cycles of “trial and error” that are centered on palliative treatment of symptoms rather than the root cause, often resulting in dubious outcomes. Recently, geroscience challenged this view, proposing that the underlying biological mechanisms of aging are central to the global increase in susceptibility to disease and disability that occurs with aging. In fact, strong correlations have recently been revealed between health dimensions and phenotypes that are typical of aging, especially with autophagy, mitochondrial function, cellular senescence, and DNA methylation. Current research focuses on measuring the pace of aging to identify individuals who are “aging faster” to test and develop interventions that could prevent or delay the progression of multimorbidity and disability with aging. Understanding how the underlying biological mechanisms of aging connect to and impact longitudinal changes in health trajectories offers a unique opportunity to identify resilience mechanisms, their dynamic changes, and their impact on stress responses. Harnessing how to evoke and control resilience mechanisms in individuals with successful aging could lead to writing a new chapter in human medicine.

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Considerations for the Use of Mutation as a Regulatory Endpoint in Risk Assessment

Klapacz

Gollapudi

2019

Environ and Mol Mutagen

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Assessment of a chemical's potential to cause permanent changes in the genetic code has been a common practice in the industry and regulatory settings for decades. Furthermore, the genetic toxicity battery of tests has typically been employed during the earliest stages of the research and development programs of new product development. A positive outcome from such battery has a major impact on the chemical's utility, industrial hygiene, product stewardship practices, and product life cycle analysis, among many other decisions that need to be taken by the industry, even before the registration of a chemical is undertaken. Under the prevailing regulatory paradigm, the dichotomous (yes/no) evaluation of the chemical's genotoxic potential leads to a conservative, linear no‐threshold (LNT) risk assessment, unless compelling and undeniable data to the contrary can be provided to satisfy regulators, typically in a number of different global jurisdictions. With the current advent of predictive methods, new testing paradigms, mode‐of‐action/adverse outcome pathways, and quantitative risk assessment approaches, various stakeholders are starting to employ these state‐of‐the‐science methodologies to further the conversation on decision making and advance the regulatory paradigm beyond the dominant LNT status quo. This commentary describes these novel methodologies, relevant biological responses, and how these can affect internal and regulatory risk assessment approaches. Environ. Mol. Mutagen. 61:84–93, 2020. © 2019 Wiley Periodicals, Inc.

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Broad spectrum detection of DNA damage by Repair Assisted Damage Detection (RADD)

Cited by 19 publications

References 31 publications

Defective base excision repair in the response to DNA damaging agents in triple negative breast cancer

Defective base excision repair in the response to DNA damaging agents in triple negative breast cancer

Measuring biological aging in humans: A quest

Considerations for the Use of Mutation as a Regulatory Endpoint in Risk Assessment

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