Your search keyword '"Reindl J"' showing total 8 results

1. Dosimetry of heavy ion exposure to human cells using nanoscopic imaging of double strand break repair protein clusters.

Author

Reindl J, Kundrat P, Girst S, Sammer M, Schwarz B, and Dollinger G

Subjects

Biomarkers, Carbon adverse effects, HeLa Cells, Humans, Linear Energy Transfer, Lithium adverse effects, Microscopy, Fluorescence methods, Phosphorylation radiation effects, Radiation Dosage, Radiation Exposure, DNA Breaks, Double-Stranded radiation effects, DNA Repair radiation effects, Gamma Rays adverse effects, Heavy Ions adverse effects, Protein Kinases radiation effects, Radiometry methods

Abstract

The human body is constantly exposed to ionizing radiation of different qualities. Especially the exposure to high-LET (linear energy transfer) particles increases due to new tumor therapy methods using e.g. carbon ions. Furthermore, upon radiation accidents, a mixture of radiation of different quality is adding up to human radiation exposure. Finally, long-term space missions such as the mission to mars pose great challenges to the dose assessment an astronaut was exposed to. Currently, DSB counting using γH2AX foci is used as an exact dosimetric measure for individuals. Due to the size of the γH2AX IRIF of ~ 0.6 µm, it is only possible to count DSB when they are separated by this distance. For high-LET particle exposure, the distance of the DSB is too small to be separated and the dose will be underestimated. In this study, we developed a method where it is possible to count DSB which are separated by a distance of ~ 140 nm. We counted the number of ionizing radiation-induced pDNA-PKcs (DNA-PKcs phosphorylated at T2609) foci (size = 140 nm ± 20 nm) in human HeLa cells using STED super-resolution microscopy that has an intrinsic resolution of 100 nm. Irradiation was performed at the ion microprobe SNAKE using high-LET 20 MeV lithium (LET = 116 keV/µm) and 27 MeV carbon ions (LET = 500 keV/µm). pDNA-PKcs foci label all DSB as proven by counterstaining with 53BP1 after low-LET γ-irradiation where separation of individual DSB is in most cases larger than the 53BP1 gross size of about 0.6 µm. Lithium ions produce (1.5 ± 0.1) IRIF/µm track length, for carbon ions (2.2 ± 0.2) IRIF/µm are counted. These values are enhanced by a factor of 2-3 compared to conventional foci counting of high-LET tracks. Comparison of the measurements to PARTRAC simulation data proof the consistency of results. We used these data to develop a measure for dosimetry of high-LET or mixed particle radiation exposure directly in the biological sample. We show that proper dosimetry for radiation up to a LET of 240 keV/µm is possible., (© 2022. The Author(s).)

Published

2022

2. Focused Ion Microbeam Irradiation Induces Clustering of DNA Double-Strand Breaks in Heterochromatin Visualized by Nanoscale-Resolution Electron Microscopy.

Author

Lorat Y, Reindl J, Isermann A, Rübe C, Friedl AA, and Rübe CE

Subjects

Cell Culture Techniques, Cluster Analysis, DNA Damage radiation effects, DNA Repair radiation effects, Euchromatin genetics, Euchromatin radiation effects, Fibroblasts, Heavy Ion Radiotherapy methods, Heavy Ions adverse effects, Heterochromatin genetics, Heterochromatin radiation effects, Humans, Ku Autoantigen genetics, Ku Autoantigen radiation effects, Linear Energy Transfer radiation effects, Microscopy, Electron methods, Radiation, Ionizing, DNA radiation effects, DNA Breaks, Double-Stranded radiation effects, Heavy Ion Radiotherapy adverse effects

Abstract

Background: Charged-particle radiotherapy is an emerging treatment modality for radioresistant tumors. The enhanced effectiveness of high-energy particles (such as heavy ions) has been related to the spatial clustering of DNA lesions due to highly localized energy deposition. Here, DNA damage patterns induced by single and multiple carbon ions were analyzed in the nuclear chromatin environment by different high-resolution microscopy approaches., Material and Methods: Using the heavy-ion microbeam SNAKE, fibroblast monolayers were irradiated with defined numbers of carbon ions (1/10/100 ions per pulse, ipp) focused to micrometer-sized stripes or spots. Radiation-induced lesions were visualized as DNA damage foci (γH2AX, 53BP1) by conventional fluorescence and stimulated emission depletion (STED) microscopy. At micro- and nanoscale level, DNA double-strand breaks (DSBs) were visualized within their chromatin context by labeling the Ku heterodimer. Single and clustered pKu70-labeled DSBs were quantified in euchromatic and heterochromatic regions at 0.1 h, 5 h and 24 h post-IR by transmission electron microscopy (TEM)., Results: Increasing numbers of carbon ions per beam spot enhanced spatial clustering of DNA lesions and increased damage complexity with two or more DSBs in close proximity. This effect was detectable in euchromatin, but was much more pronounced in heterochromatin. Analyzing the dynamics of damage processing, our findings indicate that euchromatic DSBs were processed efficiently and repaired in a timely manner. In heterochromatin, by contrast, the number of clustered DSBs continuously increased further over the first hours following IR exposure, indicating the challenging task for the cell to process highly clustered DSBs appropriately., Conclusion: Increasing numbers of carbon ions applied to sub-nuclear chromatin regions enhanced the spatial clustering of DSBs and increased damage complexity, this being more pronounced in heterochromatic regions. Inefficient processing of clustered DSBs may explain the enhanced therapeutic efficacy of particle-based radiotherapy in cancer treatment.

Published

2021

3. MODELING STUDIES ON DICENTRICS INDUCTION AFTER SUB-MICROMETER FOCUSED ION BEAM GRID IRRADIATION.

Author

Friedland W, Kundrát P, Schmitt E, Becker J, Ilicic K, Greubel C, Reindl J, Siebenwirth C, Schmid TE, and Dollinger G

Subjects

Animals, Cricetinae, Humans, Hybrid Cells cytology, Linear Energy Transfer, Models, Theoretical, Monte Carlo Method, Protons, Relative Biological Effectiveness, Chromosome Aberrations radiation effects, DNA Breaks, Double-Stranded radiation effects, Hybrid Cells radiation effects, Lymphocytes radiation effects

Abstract

The biophysical simulation tool PARTRAC contains modules for DNA damage response representing non-homologous end joining of DNA double-strand breaks (DSB) and the formation of chromosomal aberrations. Individual DNA ends from the induced DSB are followed regarding both their enzymatic processing and spatial mobility, as is needed for chromosome aberrations to arise via ligating broken ends from different chromosomes. In particular, by tracking the genomic locations of the ligated fragments and the positions of centromeres, the induction of dicentrics can be modeled. In recent experiments, the impact of spatial clustering of DNA damage on dicentric yields has been assessed in AL human-hamster hybrid cells: Defined numbers of 20 MeV protons (linear energy transfer, LET 2.6 keV/μm), 45 MeV Li ions (60 keV/μm) and 55 MeV C ions (310 keV/μm) focused to sub-μm spot sizes were applied with the ion microbeam SNAKE in diverse grid modes, keeping the absorbed dose constant. The impact of the μm-scaled spatial distribution of DSB (focusing effect) has thus been separated from nm-scaled DSB complexity (LET effect). The data provide a unique benchmark for the model calculations. Model and parameter refinements are described that enabled the simulations to largely reproduce both the LET-dependence and the focusing effect as well as the usual biphasic rejoining kinetics. The predictive power of the refined model has been benchmarked against dicentric yields for photon irradiation., (© The Author(s) 2018. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2019

4. DNA damage interactions on both nanometer and micrometer scale determine overall cellular damage.

Author

Friedrich T, Ilicic K, Greubel C, Girst S, Reindl J, Sammer M, Schwarz B, Siebenwirth C, Walsh DWM, Schmid TE, Scholz M, and Dollinger G

Subjects

DNA Repair radiation effects, Humans, Linear Energy Transfer, Radiation, Ionizing, Biophysical Phenomena, DNA Breaks, Double-Stranded radiation effects, DNA Damage radiation effects

Abstract

DNA double strand breaks (DSB) play a pivotal role for cellular damage, which is a hazard encountered in toxicology and radiation protection, but also exploited e.g. in eradicating tumors in radiation therapy. It is still debated whether and in how far clustering of such DNA lesions leads to an enhanced severity of induced damage. Here we investigate - using focused spots of ionizing radiation as damaging agent - the spatial extension of DNA lesion patterns causing cell inactivation. We find that clustering of DNA damage on both the nm and µm scale leads to enhanced inactivation compared to more homogeneous lesion distributions. A biophysical model interprets these observations in terms of enhanced DSB production and DSB interaction, respectively. We decompose the overall effects quantitatively into contributions from these lesion formation processes, concluding that both processes coexist and need to be considered for determining the resulting damage on the cellular level.

Published

2018

5. Superresolution light microscopy shows nanostructure of carbon ion radiation-induced DNA double-strand break repair foci.

Author

Lopez Perez R, Best G, Nicolay NH, Greubel C, Rossberger S, Reindl J, Dollinger G, Weber KJ, Cremer C, and Huber PE

Subjects

Cell Line, Tumor, Gene Expression Regulation, Histones genetics, Histones metabolism, Humans, DNA Breaks, Double-Stranded, DNA Repair physiology, Heavy Ion Radiotherapy, Microscopy methods

Abstract

Carbon ion radiation is a promising new form of radiotherapy for cancer, but the central question about the biologic effects of charged particle radiation is yet incompletely understood. Key to this question is the understanding of the interaction of ions with DNA in the cell's nucleus. Induction and repair of DNA lesions including double-strand breaks (DSBs) are decisive for the cell. Several DSB repair markers have been used to investigate these processes microscopically, but the limited resolution of conventional microscopy is insufficient to provide structural insights. We have applied superresolution microscopy to overcome these limitations and analyze the fine structure of DSB repair foci. We found that the conventionally detected foci of the widely used DSB marker γH2AX (Ø 700-1000 nm) were composed of elongated subfoci with a size of ∼100 nm consisting of even smaller subfocus elements (Ø 40-60 nm). The structural organization of the subfoci suggests that they could represent the local chromatin structure of elementary DSB repair units at the DSB damage sites. Subfocus clusters may indicate induction of densely spaced DSBs, which are thought to be associated with the high biologic effectiveness of carbon ions. Superresolution microscopy might emerge as a powerful tool to improve our knowledge of interactions of ionizing radiation with cells.-Lopez Perez, R., Best, G., Nicolay, N. H., Greubel, C., Rossberger, S., Reindl, J., Dollinger, G., Weber, K.-J., Cremer, C., Huber, P. E. Superresolution light microscopy shows nanostructure of carbon ion radiation-induced DNA double-strand break repair foci., (© FASEB.)

Published

2016

6. Depletion of Histone Demethylase Jarid1A Resulting in Histone Hyperacetylation and Radiation Sensitivity Does Not Affect DNA Double-Strand Break Repair.

Author

Penterling C, Drexler GA, Böhland C, Stamp R, Wilke C, Braselmann H, Caldwell RB, Reindl J, Girst S, Greubel C, Siebenwirth C, Mansour WY, Borgmann K, Dollinger G, Unger K, and Friedl AA

Subjects

Acetylation, Cell Proliferation radiation effects, Chromatin metabolism, Down-Regulation radiation effects, Gene Knockdown Techniques, Genes, Reporter, HeLa Cells, Humans, Lysine metabolism, MCF-7 Cells, Plasmids metabolism, Radiation, Ionizing, DNA Breaks, Double-Stranded radiation effects, DNA Repair radiation effects, Histones metabolism, Radiation Tolerance radiation effects, Retinoblastoma-Binding Protein 2 metabolism

Abstract

Histone demethylases have recently gained interest as potential targets in cancer treatment and several histone demethylases have been implicated in the DNA damage response. We investigated the effects of siRNA-mediated depletion of histone demethylase Jarid1A (KDM5A, RBP2), which demethylates transcription activating tri- and dimethylated lysine 4 at histone H3 (H3K4me3/me2), on growth characteristics and cellular response to radiation in several cancer cell lines. In unirradiated cells Jarid1A depletion lead to histone hyperacetylation while not affecting cell growth. In irradiated cells, depletion of Jarid1A significantly increased cellular radiosensitivity. Unexpectedly, the hyperacetylation phenotype did not lead to disturbed accumulation of DNA damage response and repair factors 53BP1, BRCA1, or Rad51 at damage sites, nor did it influence resolution of radiation-induced foci or rejoining of reporter constructs. We conclude that the radiation sensitivity observed following depletion of Jarid1A is not caused by a deficiency in repair of DNA double-strand breaks.

Published

2016

7. Nanoscopic exclusion between Rad51 and 53BP1 after ion irradiation in human HeLa cells.

Author

Reindl J, Drexler GA, Girst S, Greubel C, Siebenwirth C, Drexler SE, Dollinger G, and Friedl AA

Subjects

Cell Cycle Proteins chemistry, DNA Repair, HeLa Cells, Humans, Ions chemistry, Tumor Suppressor p53-Binding Protein 1, Carbon chemistry, DNA Breaks, Double-Stranded radiation effects, Intracellular Signaling Peptides and Proteins chemistry, Linear Energy Transfer, Protons, Rad51 Recombinase chemistry

Abstract

Many proteins involved in detection, signalling and repair of DNA double-strand breaks (DSB) accumulate in large number in the vicinity of DSB sites, forming so called foci. Emerging evidence suggests that these foci are sub-divided in structural or functional domains. We use stimulated emission depletion (STED) microscopy to investigate localization of mediator protein 53BP1 and recombination factor Rad51 after irradiation of cells with low linear energy transfer (LET) protons or high LET carbon ions. With a resolution better than 100 nm, STED microscopy and image analysis using a newly developed analyzing algorithm, the reduced product of the differences from the mean, allowed us to demonstrate that with both irradiation types Rad51 occupies spherical regions of about 200 nm diameter. These foci locate within larger 53BP1 accumulations in regions of local 53BP1 depletion, similar to what has been described for the localization of Brca1, CtIP and RPA. Furthermore, localization relative to 53BP1 and size of Rad51 foci was not different after irradiation with low and high LET radiation. As expected, 53BP1 foci induced by low LET irradiation mostly contained one Rad51 focal structure, while after high LET irradiation, most foci contained >1 Rad51 accumulation.

Published

2015

8. Sub-micrometer 20MeV protons or 45MeV lithium spot irradiation enhances yields of dicentric chromosomes due to clustering of DNA double-strand breaks.

Author

Schmid TE, Friedland W, Greubel C, Girst S, Reindl J, Siebenwirth C, Ilicic K, Schmid E, Multhoff G, Schmitt E, Kundrát P, and Dollinger G

Subjects

Animals, CHO Cells, Chromosome Aberrations, Chromosomes, Human, Pair 11 radiation effects, Cricetulus, Humans, Lithium, Models, Genetic, Models, Theoretical, Protons, Relative Biological Effectiveness, Chromosomes, Mammalian radiation effects, DNA Breaks, Double-Stranded radiation effects

Abstract

In conventional experiments on biological effects of radiation types of diverse quality, micrometer-scale double-strand break (DSB) clustering is inherently interlinked with clustering of energy deposition events on nanometer scale relevant for DSB induction. Due to this limitation, the role of the micrometer and nanometer scales in diverse biological endpoints cannot be fully separated. To address this issue, hybrid human-hamster AL cells have been irradiated with 45MeV (60keV/μm) lithium ions or 20MeV (2.6keV/μm) protons quasi-homogeneously distributed or focused to 0.5×1μm(2) spots on regular matrix patterns (point distances up to 10.6×10.6μm), with pre-defined particle numbers per spot to provide the same mean dose of 1.7Gy. The yields of dicentrics and their distribution among cells have been scored. In parallel, track-structure based simulations of DSB induction and chromosome aberration formation with PARTRAC have been performed. The results show that the sub-micrometer beam focusing does not enhance DSB yields, but significantly affects the DSB distribution within the nucleus and increases the chance to form DSB pairs in close proximity, which may lead to increased yields of chromosome aberrations. Indeed, the experiments show that focusing 20 lithium ions or 451 protons per spot on a 10.6μm grid induces two or three times more dicentrics, respectively, than a quasi-homogenous irradiation. The simulations reproduce the data in part, but in part suggest more complex behavior such as saturation or overkill not seen in the experiments. The direct experimental demonstration that sub-micrometer clustering of DSB plays a critical role in the induction of dicentrics improves the knowledge on the mechanisms by which these lethal lesions arise, and indicates how the assumptions of the biophysical model could be improved. It also provides a better understanding of the increased biological effectiveness of high-LET radiation., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published

2015