In vitro studies of the genotoxicity of ionizing radiation in human G0 T lymphocytes

O’Neill, Patrick J.; Nicklas, Janice A.; Hirsch, Betsy A.; Jostes, R. F.; Hunter, Tim; Sullivan, Linda; Albertini, Richard J.

doi:10.1002/em.20143

Cited by 13 publications

(3 citation statements)

References 57 publications

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“…In contrast, complex breaks include fragmented sugar damaged or missing bases in the vicinity of the break [64],[65]. While simple DSBs generated by endonucleases mainly cause small deletions, it is clear that a subset of random breaks leads to large deletions and translocations [43], [66]–[68]. For example, ionizing radiation induced hprt mutants resulted in deletions up to 56 kb whereas improper IgH class switching and spontaneous DSBs can lead to translocations [43], [66]–[68].…”

Section: Discussionmentioning

confidence: 99%

“…While simple DSBs generated by endonucleases mainly cause small deletions, it is clear that a subset of random breaks leads to large deletions and translocations [43], [66]–[68]. For example, ionizing radiation induced hprt mutants resulted in deletions up to 56 kb whereas improper IgH class switching and spontaneous DSBs can lead to translocations [43], [66]–[68]. Molecular characterization of large deletions and translocations revealed that they are mainly caused by microhomology-mediated repair [8],[43],[67],[69].…”

Section: Discussionmentioning

confidence: 99%

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Numt-Mediated Double-Strand Break Repair Mitigates Deletions during Primate Genome Evolution

2008

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Non-homologous end joining (NHEJ) is the major mechanism of double-strand break repair (DSBR) in mammalian cells. NHEJ has traditionally been inferred from experimental systems involving induced double strand breaks (DSBs). Whether or not the spectrum of repair events observed in experimental NHEJ reflects the repair of natural breaks by NHEJ during chromosomal evolution is an unresolved issue. In primate phylogeny, nuclear DNA sequences of mitochondrial origin, numts, are inserted into naturally occurring chromosomal breaks via NHEJ. Thus, numt integration sites harbor evidence for the mechanisms that act on the genome over evolutionary timescales. We have identified 35 and 55 lineage-specific numts in the human and chimpanzee genomes, respectively, using the rhesus monkey genome as an outgroup. One hundred and fifty two numt-chromosome fusion points were classified based on their repair patterns. Repair involving microhomology and repair leading to nucleotide additions were detected. These repair patterns are within the experimentally determined spectrum of classical NHEJ, suggesting that information from experimental systems is representative of broader genetic loci and end configurations. However, in incompatible DSBR events, small deletions always occur, whereas in 54% of numt integration events examined, no deletions were detected. Numts show a statistically significant reduction in deletion frequency, even in comparison to DSBR involving filler DNA. Therefore, numts show a unique mechanism of integration via NHEJ. Since the deletion frequency during numt insertion is low, native overhangs of chromosome breaks are preserved, allowing us to determine that 24% of the analyzed breaks are cohesive with overhangs of up to 11 bases. These data represent, to the best of our knowledge, the most comprehensive description of the structure of naturally occurring DSBs. We suggest a model in which the sealing of DSBs by numts, and probably by other filler DNA, prevents nuclear processing of DSBs that could result in deleterious repair.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Numt-Mediated Double-Strand Break Repair Mitigates Deletions during Primate Genome Evolution

2008

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“…Further analysis of CHO-K1 cells, following up from the study conducted by Hsie et al [117], failed to detect a difference between Hprt mutation spectra [118] and again in a similar contrast to some previous studies, work in human T lymphocytes [119] demonstrated less than 2% total gene deletions at the HPRT locus after exposure to radon and its daughters, although partial deletions were still present. Furthermore, human T lymphocytes exposed to high-LET radon (using the same methodology as described by Jostes et al [111]) and low-LET Caesium-137 found that the main marker of low-LET exposed lymphocytes were large deletions of the entire HPRT gene and high-LET exposure predominantly resulted in partial deletions and multiple single base changes [120]. Although not comparing high and low-LET exposures, other work in CHO cells using varying doses of Caesium-137 gamma-radiation has observed dose-dependent changes in mutation spectra [121] and a difference in mutation type between exposures of low (resulting mainly in point mutations) and high-dose (resulting in multibase deletion mutations).…”

Section: Genetic Effectsmentioning

confidence: 99%

The Cellular and Molecular Carcinogenic Effects of Radon Exposure: A Review

Robertson

Allen

Laney

et al. 2013

IJMS

120

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Radon-222 is a naturally occurring radioactive gas that is responsible for approximately half of the human annual background radiation exposure globally. Chronic exposure to radon and its decay products is estimated to be the second leading cause of lung cancer behind smoking, and links to other forms of neoplasms have been postulated. Ionizing radiation emitted during the radioactive decay of radon and its progeny can induce a variety of cytogenetic effects that can be biologically damaging and result in an increased risk of carcinogenesis. Suggested effects produced as a result of alpha particle exposure from radon include mutations, chromosome aberrations, generation of reactive oxygen species, modification of the cell cycle, up or down regulation of cytokines and the increased production of proteins associated with cell-cycle regulation and carcinogenesis. A number of potential biomarkers of exposure, including translocations at codon 249 of TP53 in addition to HPRT mutations, have been suggested although, in conclusion, the evidence for such hotspots is insufficient. There is also substantial evidence of bystander effects, which may provide complications when calculating risk estimates as a result of exposure, particularly at low doses where cellular responses often appear to deviate from the linear, no-threshold hypothesis. At low doses, effects may also be dependent on cellular conditions as opposed to dose. The cellular and molecular carcinogenic effects of radon exposure have been observed to be both numerous and complex and the elevated chronic exposure of man may therefore pose a significant public health risk that may extend beyond the association with lung carcinogenesis.

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Ion beam radiobiology and cancer: Time to update ourselves

Fokas

Kraft

et al. 2009

Biochimica et Biophysica Acta (BBA) - Reviews on Cancer

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In vitro studies of the genotoxicity of ionizing radiation in human G0 T lymphocytes

Cited by 13 publications

References 57 publications

Numt-Mediated Double-Strand Break Repair Mitigates Deletions during Primate Genome Evolution

Numt-Mediated Double-Strand Break Repair Mitigates Deletions during Primate Genome Evolution

The Cellular and Molecular Carcinogenic Effects of Radon Exposure: A Review

Ion beam radiobiology and cancer: Time to update ourselves

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