Recent groundbreaking developments in Omics and bioinformatics have generated new hope for overcoming the complexity and variability of (radio)biological systems while simultaneously shedding more light on fundamental radiobiological questions that have remained unanswered for decades. In the era of Omics, our knowledge of how genes and dozens of proteins interact in the frame of complex signaling and repair pathways (or, rather, networks) to preserve the integrity of the genome has been rapidly expanding. Nevertheless, these functional networks must be observed with strong correspondence to the cell nucleus, which is the main target of ionizing radiation. Information regarding these intricate processes cannot be achieved using high-throughput Omics approaches alone; it requires sophisticated structural probing and imaging. In the first part of this review, the article "Giving Omics Spatiotemporal Dimensions Using Exciting New Nanoscopy Techniques to Assess Complex Cell Responses to DNA Damage: Part A--Radiomics," we showed the development of different Omics solutions and how they are contributing to a better understanding of cellular radiation response. In this Part B we show how high-resolution confocal microscopy as well as novel approaches of molecular localization nanoscopy fill the gaps to successfully place Omics data in the context of space and time. The dynamics of double-strand breaks during repair processes and chromosomal rearrangements at the microscale correlated to aberration induction are explained. For the first time we visualize pan-nuclear nucleosomal rearrangements and clustering at the nanoscale during repair processes. Finally, we introduce a novel method of specific chromatin nanotargeting based on a computer database search of uniquely binding oligonucleotide combinations (COMBO-FISH). With these challenging techniques on hand, we speculate future perspectives that may combine specific COMBO-FISH nanoprobing and structural nanoscopy to observe structure-function correlations in living cells in real-time. Thus, the Omics networks obtained from function analyses may be enriched by real-time visualization of Structuromics.

Department of Radiation Oncology University Medical Center Mannheim Kirchhoff Institute for Physics University of Heidelberg Heidelberg Germany

Institute of Biochemistry and Experimental Oncology 1st Faculty of Medicine Charles University Prague Czech Republic

Institute of Biophysics Academy of Sciences of the Czech Republic Brno Czech Republic

Institute of Biophysics Academy of Sciences of the Czech Republic Brno Czech Republic; Centre for Biomedical Image Analysis Faculty of Informatics Masaryk University Brno Czech Republic

Institute of Biophysics Academy of Sciences of the Czech Republic Brno Czech Republic; Joint Institute for Nuclear Research Dubna Moscow Russia; Institute of Chemical Technology Prague Prague Czech Republic

Joint Institute for Nuclear Research Dubna Moscow Russia

Kirchhoff Institute for Physics University of Heidelberg Heidelberg Germany

Kirchhoff Institute for Physics University of Heidelberg Heidelberg Germany; Department of Radiation Oncology University Medical Center Mannheim University of Heidelberg Heidelberg Germany

Nuclear Physics Institute Academy of Sciences of the Czech Republic Rez Czech Republic

Nuclear Physics Institute Academy of Sciences of the Czech Republic Rez Czech Republic; Proton Therapy Center Prague Czech Republic

Citace poskytuje Crossref.org

Condensed Matter Systems Exposed to Radiation: Multiscale Theory, Simulations, and Experiment

Advanced image-free analysis of the nano-organization of chromatin and other biomolecules by Single Molecule Localization Microscopy (SMLM)

Spatial-Temporal Genome Regulation in Stress-Response and Cell-Fate Change

Incorporation of Low Concentrations of Gold Nanoparticles: Complex Effects on Radiation Response and Fate of Cancer Cells

DeepFoci: Deep learning-based algorithm for fast automatic analysis of DNA double-strand break ionizing radiation-induced foci

Topological Analysis of γH2AX and MRE11 Clusters Detected by Localization Microscopy during X-ray-Induced DNA Double-Strand Break Repair

Elucidation of the Clustered Nano-Architecture of Radiation-Induced DNA Damage Sites and Surrounding Chromatin in Cancer Cells: A Single Molecule Localization Microscopy Approach

A Paradigm Revolution or Just Better Resolution-Will Newly Emerging Superresolution Techniques Identify Chromatin Architecture as a Key Factor in Radiation-Induced DNA Damage and Repair Regulation?

Challenges and Contradictions of Metal Nano-Particle Applications for Radio-Sensitivity Enhancement in Cancer Therapy

Recruitment of 53BP1 Proteins for DNA Repair and Persistence of Repair Clusters Differ for Cell Types as Detected by Single Molecule Localization Microscopy