Please use this identifier to cite or link to this item: doi:10.22028/D291-40881
Title: Automated Image Analysis of Transmission Electron Micrographs: Nanoscale Evaluation of Radiation-Induced DNA Damage in the Context of Chromatin
Author(s): Abd Al-razaq, Mutaz A.
Isermann, Anna
Hecht, Markus
Rübe, Claudia E.
Language: English
Title: Cells
Volume: 12
Issue: 20
Publisher/Platform: MDPI
Year of Publication: 2023
Free key words: automated image analysis
transmission electron microscopy (TEM)
heavy ion irradiation
linear energy transfer (LET)
DNA damage
DNA double-strand breaks (DSBs)
chromatin remodelling
DDC notations: 610 Medicine and health
Publikation type: Journal Article
Abstract: Background: Heavy ion irradiation (IR) with high-linear energy transfer (LET) is characterized by a unique depth dose distribution and increased biological effectiveness. Following high-LET IR, localized energy deposition along the particle trajectories induces clustered DNA lesions, leading to low electron density domains (LEDDs). To investigate the spatiotemporal dynamics of DNA repair and chromatin remodeling, we established the automated image analysis of transmission electron micrographs. Methods: Human fibroblasts were irradiated with high-LET carbon ions or low-LET photons. At 0.1 h, 0.5 h, 5 h, and 24 h post-IR, nanoparticle-labeled repair factors (53BP1, pKu70, pKu80, DNA-PKcs) were visualized using transmission electron microscopy in interphase nuclei to monitor the formation and repair of DNA damage in the chromatin ultrastructure. Using AI-based software tools, advanced image analysis techniques were established to assess the DNA damage pattern following low-LET versus high-LET IR. Results: Low-LET IR induced single DNA lesions throughout the nucleus, and most DNA double-strand breaks (DSBs) were efficiently rejoined with no visible chromatin decondensation. High-LET IR induced clustered DNA damage concentrated along the particle trajectories, resulting in circumscribed LEDDs. Automated image analysis was used to determine the exact number of differently sized nanoparticles, their distance from one another, and their precise location within the micrographs (based on size, shape, and density). Chromatin densities were determined from grayscale features, and nanoparticles were automatically assigned to euchromatin or heterochromatin. High-LET IR-induced LEDDs were delineated using automated segmentation, and the spatial distribution of nanoparticles in relation to segmented LEDDs was determined. Conclusions: The results of our image analysis suggest that high-LET IR induces chromatin relaxation along particle trajectories, enabling the critical repair of successive DNA damage. Following exposure to different radiation qualities, automated image analysis of nanoparticle-labeled DNA repair proteins in the chromatin ultrastructure enables precise characterization of specific DNA damage patterns.
DOI of the first publication: 10.3390/cells12202427
URL of the first publication: https://doi.org/10.3390/cells12202427
Link to this record: urn:nbn:de:bsz:291--ds-408815
hdl:20.500.11880/36758
http://dx.doi.org/10.22028/D291-40881
ISSN: 2073-4409
Date of registration: 6-Nov-2023
Faculty: M - Medizinische Fakultät
Department: M - Radiologie
Professorship: M - Prof. Dr. Christian Rübe
Collections:SciDok - Der Wissenschaftsserver der Universität des Saarlandes

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