Chromatin differentiation of white blood cells decreases DSB damage induction, prevents functional assembly of repair foci, but has no influence on protrusion of heterochromatic DSBs into the low-dense chromatin

Falk, Martin; Lukášová, Emı́lie; Falková, Iva; Štefančíková, Lenka; Ježková, Lucie; Bačı́ková, Alena; Davídková, Marie; Boreyko, A. V.; Krasavin, E. A.; Kozubek, Stanislav

doi:10.1093/jrr/rrt194

Cited by 5 publications

(2 citation statements)

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“…Hence, we used independent immunolabelling of two DSBs markers—γH2AX and 53BP1—in combination with high-resolution confocal microscopy [ 82 ]. According to our best knowledge, this approach increases the accuracy of the DSBs recognition [ 83 – 86 ], and has not been used in earlier studies.…”

Section: Discussionmentioning

confidence: 99%

Effect of gadolinium-based nanoparticles on nuclear DNA damage and repair in glioblastoma tumor cells

et al. 2016

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BackgroundTumor targeting of radiotherapy represents a great challenge. The addition of multimodal nanoparticles, such as 3 nm gadolinium-based nanoparticles (GdBNs), has been proposed as a promising strategy to amplify the effects of radiation in tumors and improve diagnostics using the same agents. This singular property named theranostic is a unique advantage of GdBNs. It has been established that the amplification of radiation effects by GdBNs appears due to fast electronic processes. However, the influence of these nanoparticles on cells is not yet understood. In particular, it remains dubious how nanoparticles activated by ionizing radiation interact with cells and their constituents. A crucial question remains open of whether damage to the nucleus is necessary for the radiosensitization exerted by GdBNs (and other nanoparticles).MethodsWe studied the effect of GdBNs on the induction and repair of DNA double-strand breaks (DSBs) in the nuclear DNA of U87 tumor cells irradiated with γ-rays. For this purpose, we used currently the most sensitive method of DSBs detection based on high-resolution confocal fluorescence microscopy coupled with immunodetection of two independent DSBs markers.ResultsWe show that, in the conditions where GdBNs amplify radiation effects, they remain localized in the cytoplasm, i.e. do not penetrate into the nucleus. In addition, the presence of GdBNs in the cytoplasm neither increases induction of DSBs by γ-rays in the nuclear DNA nor affects their consequent repair.ConclusionsOur results suggest that the radiosensitization mediated by GdBNs is a cytoplasmic event that is independent of the nuclear DNA breakage, a phenomenon commonly accepted as the explanation of biological radiation effects. Considering our earlier recognized colocalization of GdBNs with the lysosomes and endosomes, we revolutionary hypothesize here about these organelles as potential targets for (some) nanoparticles. If confirmed, this finding of cytoplasmically determined radiosensitization opens new perspectives of using nano-radioenhancers to improve radiotherapy without escalating the risk of pathologies related to genetic damage.

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Section: Discussionmentioning

confidence: 99%

Effect of gadolinium-based nanoparticles on nuclear DNA damage and repair in glioblastoma tumor cells

et al. 2016

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“…Hence, we used independent immunolabelling of two DSBs markers-γH2AX and 53BP1-in combination with high-resolution confocal microscopy [82]. According to our best knowledge, this approach increases the accuracy of the DSBs recognition [83][84][85][86], and has not been used in earlier studies.…”

Section: Nanoparticle Surface Modifications and Labelingmentioning

confidence: 99%

Effect of gadolinium-based nanoparticles on nuclear DNA damage and repair in glioblastoma tumor cells

Štefančíková¹,

Lacombe²,

Salado³

et al. 2017

Nano Online

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Background: Tumor targeting of radiotherapy represents a great challenge. The addition of multimodal nanoparticles, such as 3 nm gadolinium-based nanoparticles (GdBNs), has been proposed as a promising strategy to amplify the effects of radiation in tumors and improve diagnostics using the same agents. This singular property named theranostic is a unique advantage of GdBNs. It has been established that the amplification of radiation effects by GdBNs appears due to fast electronic processes. However, the influence of these nanoparticles on cells is not yet understood. In particular, it remains dubious how nanoparticles activated by ionizing radiation interact with cells and their constituents. A crucial question remains open of whether damage to the nucleus is necessary for the radiosensitization exerted by GdBNs (and other nanoparticles). Methods: We studied the effect of GdBNs on the induction and repair of DNA double-strand breaks (DSBs) in the nuclear DNA of U87 tumor cells irradiated with γ-rays. For this purpose, we used currently the most sensitive method of DSBs detection based on high-resolution confocal fluorescence microscopy coupled with immunodetection of two independent DSBs markers. Results: We show that, in the conditions where GdBNs amplify radiation effects, they remain localized in the cytoplasm, i.e. do not penetrate into the nucleus. In addition, the presence of GdBNs in the cytoplasm neither increases induction of DSBs by γ-rays in the nuclear DNA nor affects their consequent repair. Conclusions: Our results suggest that the radiosensitization mediated by GdBNs is a cytoplasmic event that is independent of the nuclear DNA breakage, a phenomenon commonly accepted as the explanation of biological radiation effects. Considering our earlier recognized colocalization of GdBNs with the lysosomes and endosomes, we revolutionary hypothesize here about these organelles as potential targets for (some) nanoparticles. If confirmed, this finding of cytoplasmically determined radiosensitization opens new perspectives of using nano-radioenhancers to improve radiotherapy without escalating the risk of pathologies related to genetic damage.

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Radiobiological research at JINR's accelerators

Krasavin¹

2016

Phys.-Usp.

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Chromatin differentiation of white blood cells decreases DSB damage induction, prevents functional assembly of repair foci, but has no influence on protrusion of heterochromatic DSBs into the low-dense chromatin

Cited by 5 publications

References 5 publications

Effect of gadolinium-based nanoparticles on nuclear DNA damage and repair in glioblastoma tumor cells

Effect of gadolinium-based nanoparticles on nuclear DNA damage and repair in glioblastoma tumor cells

Effect of gadolinium-based nanoparticles on nuclear DNA damage and repair in glioblastoma tumor cells

Radiobiological research at JINR's accelerators

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