This paper has been prepared to commemorate the 70th anniversary of the Institute of Biophysics of the Czech Academy of Sciences (IBP CAS), which has a long-standing tradition in researching the biological effects of ionizing radiation (IR). Radiobiology has recently gained renewed importance due to several compelling factors. The demand for a better understanding of the biological effects of both low and high doses of various types of ionizing radiation, along with improved radiation protection, is increasing-particularly in the context of critical ongoing human activities such as medical diagnostics, radiotherapy, and the operation of nuclear power plants. This demand also extends to newly emerging scenarios, including the development of hadron and FLASH radiotherapy, as well as mixed radiation field exposures related to planned manned missions to Mars. Unfortunately, there is also an urgent need to address the heightened risk of nuclear materials and weapons misuse by terrorists or even rogue states. Additionally, nuclear energy is currently the only viable alternative that can provide efficient, sustainable, and ecological coverage for the dramatically increasing current and future energy demands. Understanding the risks of IR exposure necessitates exploring how different types of IR interact with living organisms at the most fundamental level of complexity, specifically at the level of molecules and their complexes. The rising interest in radiobiology is, therefore, also driven by new experimental opportunities that enable research at previously unimaginable levels of detail and complexity. In this manuscript, we will address the important questions in radiobiology, focusing specifically on the mechanisms of radiation-induced DNA damage and repair within the context of chromatin architecture. We will emphasize the differing effects of photon and high-LET particle radiation on chromatin and DNA. Both forms of IR are encountered on Earth but are particularly significant in space.

• Keywords
• Biological effects of ionizing radiation, Chromatin architecture at micro- and nano-scale, DNA damage and repair, Densely ionizing (high-LET) particle radiation, Institute of biophysics of the Czech academy of sciences, Microscopy, Photon radiation, Radiobiological research, Single molecule localization microscopy (SMLM),
• Publication type
• Journal Article MeSH
• Review MeSH

Complex functioning of the genome in the cell nucleus is controlled at different levels: (a) the DNA base sequence containing all relevant inherited information; (b) epigenetic pathways consisting of protein interactions and feedback loops; (c) the genome architecture and organization activating or suppressing genetic interactions between different parts of the genome. Most research so far has shed light on the puzzle pieces at these levels. This article, however, attempts an integrative approach to genome expression regulation incorporating these different layers. Under environmental stress or during cell development, differentiation towards specialized cell types, or to dysfunctional tumor, the cell nucleus seems to react as a whole through coordinated changes at all levels of control. This implies the need for a framework in which biological, chemical, and physical manifestations can serve as a basis for a coherent theory of gene self-organization. An international symposium held at the Biomedical Research and Study Center in Riga, Latvia, on 25 July 2022 addressed novel aspects of the abovementioned topic. The present article reviews the most recent results and conclusions of the state-of-the-art research in this multidisciplinary field of science, which were delivered and discussed by scholars at the Riga symposium.

• Keywords
• database pattern analysis, dynamic genome organization, epigenetic interactions, fluorescence microscopy, gene activity oscillations, heterochromatin and self-organization, nucleotide k-mers, organizational and functional networks, topological genome analysis, transposon-effected regulation,
• MeSH
• Cell Differentiation genetics   MeSH
• Cell Nucleus * metabolism   MeSH
• Genome * MeSH
• Publication type
• Congress MeSH
• Review MeSH

In cancer therapy, the application of (fractionated) harsh radiation treatment is state of the art for many types of tumors. However, ionizing radiation is a "double-edged sword"-it can kill the tumor but can also promote the selection of radioresistant tumor cell clones or even initiate carcinogenesis in the normal irradiated tissue. Individualized radiotherapy would reduce these risks and boost the treatment, but its development requires a deep understanding of DNA damage and repair processes and the corresponding control mechanisms. DNA double strand breaks (DSBs) and their repair play a critical role in the cellular response to radiation. In previous years, it has become apparent that, beyond genetic and epigenetic determinants, the structural aspects of damaged chromatin (i.e., not only of DSBs themselves but also of the whole damage-surrounding chromatin domains) form another layer of complex DSB regulation. In the present article, we summarize the application of super-resolution single molecule localization microscopy (SMLM) for investigations of these structural aspects with emphasis on the relationship between the nano-architecture of radiation-induced repair foci (IRIFs), represented here by γH2AX foci, and their chromatin environment. Using irradiated HeLa cell cultures as an example, we show repair-dependent rearrangements of damaged chromatin and analyze the architecture of γH2AX repair clusters according to topological similarities. Although HeLa cells are known to have highly aberrant genomes, the topological similarity of γH2AX was high, indicating a functional, presumptively genome type-independent relevance of structural aspects in DSB repair. Remarkably, nano-scaled chromatin rearrangements during repair depended both on the chromatin domain type and the treatment. Based on these results, we demonstrate how the nano-architecture and topology of IRIFs and chromatin can be determined, point to the methodological relevance of SMLM, and discuss the consequences of the observed phenomena for the DSB repair network regulation or, for instance, radiation treatment outcomes.

• Keywords
• chromatin rearrangements after irradiation, ionizing radiation-induced foci (IRIF), nano-architecture, single molecule localization microscopy (SMLM), topology of DNA double strand breaks,
• MeSH
• Chromatin genetics   ultrastructure   MeSH
• DNA Breaks, Double-Stranded radiation effects   MeSH
• HeLa Cells MeSH
• Radiation, Ionizing MeSH
• Humans MeSH
• Microscopy methods   MeSH
• Cell Line, Tumor MeSH
• Neoplasms genetics   MeSH
• DNA Repair genetics   radiation effects   MeSH
• DNA Damage genetics   radiation effects   MeSH
• Single Molecule Imaging methods   MeSH
• Check Tag
• Humans MeSH
• Publication type
• Journal Article MeSH
• Names of Substances
• Chromatin MeSH

To determine the influence of increased gene expression and amplification in colorectal carcinoma on chromatin structure, the nuclear distances between pairs of bacterial artificial chromosome (BAC) clones with genomic separation from 800 to 29,000 kb were measured and compared between the tumor and parallel epithelial cells of six patients. The nuclear distances were measured between the loci in chromosomal bands 7p22.3-7p21.3; 7q35-7q36.3; 11p15.5-11p15.4; 20p13; 20p12.2; 20q11.21 and 20q12 where increased expression had been found in all types of colorectal carcinoma. The loci were visualized by three-dimensional fluorescence in situ hybridization using 22 BAC clones. Our results show that for short genomic separations, mean nuclear distance increases linearly with increased genomic separation. The results for some pairs of loci fell outside this linear slope, indicating the existence of different levels of chromatin folding. For the same genomic separations the nuclear distances were frequently shorter for tumor as compared with epithelial cells. Above the initial growing phase of the nuclear distances, a plateau phase was observed in both cell types where the increase in genomic separation was not accompanied by an increase in nuclear distance. The ratio of the mean nuclear distances between the corresponding loci in tumor and epithelium cells decreases with increasing amplification of loci. Our results further show that the large-scale chromatin folding might differ for specific regions of chromosomes and that it is basically preserved in tumor cells in spite of the amplification of many loci.

• MeSH
• Gene Amplification genetics   MeSH
• Cell Nucleus genetics   ultrastructure   MeSH
• Chromatin genetics   ultrastructure   MeSH
• DNA, Neoplasm genetics   MeSH
• DNA Probes MeSH
• Adult MeSH
• Epithelial Cells pathology   MeSH
• In Situ Hybridization, Fluorescence MeSH
• Colorectal Neoplasms genetics   pathology   MeSH
• Middle Aged MeSH
• Humans MeSH
• Chromosomes, Human genetics   ultrastructure   MeSH
• Chromosome Banding MeSH
• Aged MeSH
• Check Tag
• Adult MeSH
• Middle Aged MeSH
• Humans MeSH
• Male MeSH
• Aged MeSH
• Female MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH
• Names of Substances
• Chromatin MeSH
• DNA, Neoplasm MeSH
• DNA Probes MeSH