Ionizing radiation (IR)-induced damage confers functional and conformational changes to nuclear chromatin associated with DNA single and double strand breaks. This leads to the activation of complex DNA repair machineries that aim to preserve the integrity of the DNA molecule. Since hetero- and euchromatin are differentially accessible to DNA repair pathways, local chromatin re-arrangements and structural changes are among the consequences of an activated DNA damage response. Using super-resolution localization microscopy (SRLM), we investigated the X-ray-induced repositioning of γ-H2AX and histone H3K9me3 heterochromatin marks in the nuclei of HeLa cells. Aliquots of cells exposed to different IR doses (0.5, 1 and 2 Gy) were fixed at certain repair times for SRLM imaging. The number and size of nano-scale γ-H2AX molecule signal clusters detected increased with rising irradiation doses, with the number and size being the highest 0.5 h after irradiation. With growing repair time both the number and size of γ-H2AX nano-clusters decreased. Eight hours after irradiation, the number of clusters reached control levels, in agreement with the disappearance of most IR-induced foci seen by conventional microscopy. SRLM investigation of heterochromatin marks in spatial relation to γ-H2AX clusters showed that on average the heterochromatin density was high in the vicinity of γ-H2AX, which is in agreement with the observation that DSBs seem to relocate to the surface of heterochromatin clusters for DNA repair. The data demonstrate the potential of pointillist images obtained by SRLM for quantitative investigations of chromatin conformation changes and repair-protein recruitment on the nanoscale as measures for a radiation response.
Understanding molecular interactions and regulatory mechanisms in tumor initiation, progression, and treatment response are key requirements towards advanced cancer diagnosis and novel treatment procedures in personalized medicine. Beyond decoding the gene expression, malfunctioning and cancer-related epigenetic pathways, investigations of the spatial receptor arrangements in membranes and genome organization in cell nuclei, on the nano-scale, contribute to elucidating complex molecular mechanisms in cells and tissues. By these means, the correlation between cell function and spatial organization of molecules or molecular complexes can be studied, with respect to carcinogenesis, tumor sensitivity or tumor resistance to anticancer therapies, like radiation or antibody treatment. Here, we present several new applications for bio-molecular nano-probes and super-resolution, laser fluorescence localization microscopy and their potential in life sciences, especially in biomedical and cancer research. By means of a tool-box of fluorescent antibodies, green fluorescent protein (GFP) tagging, or specific oligonucleotides, we present tumor relevant re-arrangements of Erb-receptors in membranes, spatial organization of Smad specific ubiquitin protein ligase 2 (Smurf2) in the cytosol, tumor cell characteristic heterochromatin organization, and molecular re-arrangements induced by radiation or antibody treatment. The main purpose of this article is to demonstrate how nano-scaled distance measurements between bio-molecules, tagged by appropriate nano-probes, can be applied to elucidate structures and conformations of molecular complexes which are characteristic of tumorigenesis and treatment responses. These applications open new avenues towards a better interpretation of the spatial organization and treatment responses of functionally relevant molecules, at the single cell level, in normal and cancer cells, offering new potentials for individualized medicine.
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