Abstract
Immunostaining and fluorescence in situ hybridization (FISH) are well established methods for specific labelling of chromatin in the cell nucleus. COMBO-FISH (combinatorial oligonucleotide fluorescence in situ hybridization) is a FISH method using computer designed oligonucleotide probes specifically co-localizing at given target sites. In combination with super resolution microscopy which achieves spatial resolution far beyond the Abbe Limit, it allows new insights into the nano-scaled structure and organization of the chromatin of the nucleus. To avoid nano-structural changes of the chromatin, the COMBO-FISH labelling protocol was optimized omitting heat treatment for denaturation of the target. As an example, this protocol was applied to ALU elements—dispersed short stretches of DNA which appear in different kinds in large numbers in primate genomes. These ALU elements seem to be involved in gene regulation, genomic diversity, disease induction, DNA repair, etc. By computer search, we developed a unique COMBO-FISH probe which specifically binds to ALU consensus elements and combined this DNA–DNA labelling procedure with heterochromatin immunostainings in formaldehyde-fixed cell specimens. By localization microscopy, the chromatin network-like arrangements of ALU oligonucleotide repeats and heterochromatin antibody labelling sites were simultaneously visualized and quantified. This novel approach which simultaneously combines COMBO-FISH and immunostaining was applied to chromatin analysis on the nanoscale after low-linear-energy-transfer (LET) radiation exposure at different doses. Dose-correlated curves were obtained from the amount of ALU representing signals, and the chromatin re-arrangements during DNA repair after irradiation were quantitatively studied on the nano-scale. Beyond applications in radiation research, the labelling strategy of immunostaining and COMBO-FISH with localization microscopy will also offer new potentials for analyses of subcellular elements in combination with other specific chromatin targets.
Highlights
Fluorescence in situ hybridization (FISH) using target-specific DNA probes as well as immunostaining using specific antibodies have each become routine techniques in modern molecular biology, cell research, and medical diagnosis [1]
We developed a unique combinatorial oligonucleotide (COMBO)-fluorescence in situ hybridization (FISH) probe which binds to ALU consensus elements and combined this DNA–DNA labelling procedure with heterochromatin immunostainings in formaldehyde-fixed cell specimens
We present a method to analyze the chromatin organization of ALU elements and its heterochromatic environment in intact cell nuclei using an optimized low-temperature DNA-hybridization-protocol for chromatin FISH in combination with immunostaining, super-resolution localization microscopy, and in-house-developed computer-based methods for structural analysis
Summary
Fluorescence in situ hybridization (FISH) using target-specific DNA probes as well as immunostaining using specific antibodies have each become routine techniques in modern molecular biology, cell research, and medical diagnosis [1]. Experiments combining both techniques simultaneously in combination with high-resolution microscopy (a review about high-resolution microscopy is presented in [2,3]) are still challenging because of the different protocol essentials and their influence on the examined structure [4]. A challenge that must not be underestimated in this context of circumventing possible limits is the development of adequate computer-based analysis methods for the evaluation of the high-resolution data
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