Abstract
Currently, in the context of radiology, irradiation-induced and other genotoxic effects are determined by visualizing DSB-induced DNA repair through γ-H2AX immunofluorescence and direct counting of the foci by epifluorescence microscopy. This procedure, however, neglects the 3D nature of the nucleus. The aim of our study was to use confocal microscopy and 3D reconstructed images to improve documentation and analysis of γ-H2AX fluorescence signals after diagnostic examinations. Confluent, non-dividing MRC-5 lung fibroblasts were irradiated in vitro with a Cs-137 source and exposed to radiation doses up to 1000 mGy before fixation and staining with an antibody recognizing the phosphorylated histone variant γ-H2AX. The 3D distribution of γ-H2AX foci was visualized using confocal laser scanning microscopy. 3D reconstruction of the optical slices and γ-H2AX foci counting were performed using Imaris Image Analysis software. In parallel, γ-H2AX foci were counted visually by epifluorescence microscopy. In addition, whole blood was exposed ex vivo to the radiation doses from 200 to 1600 mGy. White blood cells (WBCs) were isolated and stained for γ-H2AX. In fibroblasts, epifluorescence microscopy alone visualized the entirety of fluorescence signals as integral, without correct demarcation of single foci, and at 1000 mGy yielded on average 11.1 foci by manual counting of 2D images in comparison to 36.1 foci with confocal microscopy and 3D reconstruction (p < 0.001). The procedure can also be applied for studies on WBCs. In contrast to epifluorescence microscopy, confocal microscopy and 3D reconstruction enables an improved identification of DSB-induced γ-H2AX foci, allowing for an unbiased, ameliorated quantification.
Introduction
Maintaining the genome integrity and stability is one central function of all cells. In particular, in higher organisms, mutations on the basis of DNA double strand breaks (DSBs) may be harmful, because they could be the origin of cancer (Berrington de Gonzalez and Darby 2004; Lobrich and Jeggo 2007). Knowledge about genotoxicity, its sources, the principle of DNA-repair mechanisms, and the analysis of DNA DSBs is very important to either increase (treatment regimens in oncology) or to minimize its influence. The latter is aimed at diagnostic radiologic X-ray-based procedures: an as-much-as-possible minimalized degree of radiation-induced DNA damage is mandatory in CT-scans and interventional procedures.
DNA damage includes a wide range of DNA base modifications, single-strand breaks (SSBs) and DSBs, which are a threat to genome stability (Tounekti et al. 2001). To maintain genome stability, there are several cellular repair mechanisms operating (Symington and Gautier 2011). If DSBs occur due to exogenous agents, such as ionizing radiation or during programmed recombination events, one of the first observed cellular responses is the rapid phosphorylation of the histone protein H2AX at serine 139 (Burma et al. 2001; Rogakou et al. 1998; Chen et al. 2000). Phosphorylation of H2AX involves the phosphatidylinositol 3-kinase family consisting of ataxia telangiectasia mutated (ATM), DNA-dependent protein kinase, ataxia telangiectasia and Rad3-related (ATR) kinases (Ward and Chen 2001; Stiff et al. 2004; Wang et al. 2005). The phosphorylated H2AX, termed γ-H2AX, is recognized by a specific antibody and serves as a molecular marker to visualize the onset of DNA DSB-induced DNA repair (Pilch et al. 2003; Sedelnikova et al. 2002). Various techniques are known to visualize γ-H2AX. The intensity of the fluorescence labelled anti- γ-H2AX antibody is measured by fluorescence-activated cell sorting or by counting foci using epifluorescence microscopy (Muslimovic et al. 2008; van Oorschot et al. 2016; Fasshauer et al. 2017; Lassmann et al. 2010; Wang et al. 2016).
Currently, in the context of radiology, irradiation-induced DSBs after computed tomography examinations are analyzed in peripheral blood lymphocytes nuclei using the γ-H2AX immunofluorescence method to visualize the onset of DNA DSB-induced DNA repair (Kuefner et al. 2010b, 2009; Piechowiak et al. 2015; Geisel et al. 2008; Pathe et al. 2011; Deinzer et al. 2014; Reddig et al. 2017). A disadvantage of the method is the fact that the 3D nature of the nucleus is rarely taken into account (Tao et al. 2018; Kuefner et al. 2010a; Piechowiak et al. 2015; Wang et al. 2017). Using epifluorescence microscopy, the entirety of fluorescence signals is visualized as integral without clear delineation of single foci. Therefore, the aim of this study was to use confocal microscopy and 3D reconstructed images to enable improved documentation and analysis of γ-H2AX fluorescence signals in the context of clinical radiology.
Materials and methods
Cell culture and irradiation
MRC-5 cells, primary human fibroblasts, from the lung were purchased from American Type Culture Collection (ATCC, Manassas, VA, USA) and grown, on coverslips, in DMEM/Ham’s F-12 (1/1), complemented with 10% fetal bovine serum.
Confluent, non-dividing MRC-5 cells were exposed to the following radiation doses: 0, 200, 300, 400, 500, and 1000 mGy using a Gammacell 40 Exactor with a central dose rate of 1000 mGy/minute at room temperature (Nordion International, Ottawa, Canada). Sham-irradiation was performed as described for the test samples but without irradiation. Exposed samples were kept for 10 min in a humidified incubator (37 °C, 5% CO2 in air) before fixation with acetone–methanol [1/1 (vol/vol)] for 5 min at − 20 °C.
Blood collection and irradiation
All studies have been done in accordance with the Code of Ethics of the World Medical Association (Declaration of Helsinki) for experiments involving humans. Peripheral venous blood samples of healthy staff volunteers were collected in heparinized tubes (Sarstedt, Nümbrecht, Germany).
Whole blood was exposed in vitro to the following radiation doses of 0, 200, 400, 800, and 1600 mGy by a Gammacell 40 Exactor at room temperature. For control, cells were sham-irradiated in all experiments.
To isolate WBCs, 200 µL blood of each sample after 10 min incubation at 37 °C was mixed with 1 mL eBioscience™ 1-Step Fix/Lyse solution (Thermo Scientific, Weltham, MA, USA Jersey, USA) and incubated for 10 min at RT. WBCs were sedimented in a bench-top centrifuge for 2 min at 480×g and washed once with phosphate-buffered saline pH 7.4 (PBS). The WBCs were resuspended in 20 µL PBS, transferred onto a glass cover and were fixed with acetone–methanol [1/1 (vol/vol)] for 5 min at − 20 °C.
Immunofluorescence
Fixed specimens were incubated with monoclonal anti-γ-H2AX Ab (1:500 dilution, Merck Millipore, Billerica, MA, USA) for 1 h at room temperature, washed, and stained using Alexa™ 488-conjugated goat anti-mouse secondary antibody (1:500 dilution, Molecular Probes, Eugene, OR, USA) for 1 h at room temperature in the dark. Cells were washed and incubated with DAPI for 1 min and mounted with Dako fluorescent mounting medium (Dako, Carpinteria, CA, USA).
Microscopy
The 3D distribution of γ-H2AX foci was visualized using confocal laser scanning microscopy with a 63x magnification objective (Zeiss LSM 880 confocal microscope with Airyscan). The nucleus was visualized by DAPI. An Argon 488 nm laser and a 405 nm diode laser were used to acquire images. DAPI was imaged by detection between 410 and 495 nm, and Alexa™ 488 labelled anti-γ-H2AX Ab was detected between 499 and 552 nm. To determine the real number, size, and spatial arrangement of DSBs existing inside it, optical slices with 600 nm intervals were performed (scaling per pixel: 0.290 µm × 0.290 µm × 0.608 µm). For each field of view about 25–35 optical slices were usually obtained and used for either maximal intensity projections or 3D reconstructions. Maximum intensity projection was performed of Z-stacks by Zeiss Zen software (Carl Zeiss AG, Oberkochen, Germany). In addition, γ-H2AX foci were visualized by epifluorescence microscopy (Zeiss Axiovert microscope).
3D reconstruction
Acquired confocal Z-stacks comprising up to 35 images were reconstructed into 3D using Imaris image analysis software (Bitplane AG, Zurich, Switzerland). The volumes of the nuclei (DAPI) and of the γ-H2AX (Alexa™ 488) foci were segmented using the absolute intensity threshold whose identification is of crucial importance. Nuclear and γ-H2AX volumes were obtained separately. Touching objects were split by the calculated seed points inside each area.
Quantification of γ-H2AX foci
For quantification of γ-H2AX foci by confocal microscopy plus 3D reconstruction, a field of ≥ 20 nuclei stained by DAPI only was selected to exclude bias. Parameters used for DNA DSB-counts and of the number of nuclei as well (seed points, intensity, and number of voxels) were kept constant, within one series of experiments, for all radiation doses. Touching objects were separated with a guide size of 0.5 µm; however, filter-type quality varied, and were adjusted for optimal signal/noise ratios. Further, foci were counted of a maximum projection image by eye.
In parallel, γ-H2AX foci were counted visually by epifluorescence microscopy through the ocular. A field of about 20 nuclei was selected by DAPI staining as above. Four people blinded for the experimental design counted the γ-H2AX foci visually.
Results
Microscopy
DNA DSBs (green signal) were examined by confocal microscopy and by epifluorescence microscopy after an irradiation dose of 1000 mGy. Using confocal microscopy, all induced DSBs identifiable in the nucleus (blue signal) were displayed. They resided on different Z-planes. In contrast, by epifluorescence microscopy the entirety of fluorescence signals was visualized as integral without clear demarcation of single foci (Fig. 1).
We investigated the induction of DSBs in confluent cultures of primary MRC-5 fibroblasts exposed to increasing radiation doses. As shown in Fig. 2, the visible increase in γ-H2AX foci initially correlates with the applied radiation dose.
3D reconstruction
The Z-stacks obtained by confocal microscopy were used for the reconstruction and segmentation of cell nuclei and γ-H2AX foci volumes shown in Fig. 3. Seed points (white spheres) were calculated within each surface to split objects and were used for 3D counting analysis. The visible seed points in Fig. 3c, represent γ-H2AX foci and were used for DSB quantification.
Quantification of γ-H2AX
To test DSB quantification using confocal microscopy, γ-H2AX foci were counted with the Imaris software after 3D reconstruction as described. In parallel, images were counted visually of the same irradiated samples using an epifluorescence microscope. Dose–response curves for γ-H2AX foci in irradiated MRC-5 cells up to 1000 mGy was obtained by confocal microscopy plus 3D reconstruction, by maximum intensity projection images of the optical slices or by an epifluorescence microscope analysis (Fig. 4). Comparison shows that the mean number of DSBs per nucleus counted by Imaris software after 3D reconstruction yields higher DSBs/nucleus than determined visually (Table 1; Fig. 4.). The average number determined by epifluorescence microscope for 200 mGy, was 2.4 ± 0.8 DSBs per cell nucleus. At 500 mGy and 1000 mGy exposure, 6.7 ± 2.0 and 11.1 ± 2.1 DSBs were counted per cell nucleus, respectively. In contrast, in two independent experiments the 3D distribution of γ-H2AX foci counted by Imaris software yielded an average number of 13.8 ± 1.6 DSBs per cell nucleus for 200 mGy. An average of 23 ± 4.2 DSBs were counted by 500 mGy and 36.1 ± 3.5 DSBs per cell nucleus by 1000 mGy. When the number of γ-H2AX foci was analyzed by maximum intensity projection images, an average number of 4.4 ± 1.9 DSBs per cell nucleus was counted for 200 mGy. An average of 12.4 ± 4.1 DSBs were counted by 500 mGy and 17.4 ± 3.0 DSBs per cell nucleus by 1000 mGy.
In addition, the ratio between confocal microscopy and 3D reconstruction and epifluorescence microscope was calculated. The ratio for 200 mGy was 5.8 ± 2.0. A 3.4 ± 1.2 fold higher number of DSBs compared to epifluorescence microscopy was calculated for 500 mGy. At 1000 mGy exposure the calculated ratio was 3.3 ± 0.7.
Comparison of the values obtained by 3D reconstructed images with foci counted on major intensity projection images or the numbers resulting from epifluorescence microscopy by statistical means clearly showed that except for the non-irradiated samples the numbers were significantly different. Statistical analysis was carried out using a multiple unpaired t test on the two curves and statistical significance was determined using the Holm–Sidak method, with alpha = 0.05 (Holm 1979). The p values obtained were > 0.3 for the non-irradiated cells and < 0.001 for the irradiated cells, respectively (Table 1).
Moreover, the quantification of DNA DSB foci by confocal microscopy followed by 3D reconstruction may be used as biologic dosimeter for radiation exposure. To this end, blood samples were irradiated in the dose range from 0.2 to 1.6 Gy and stained for γ-H2AX. Acquired image stacks were 3D reconstructed, and γ-H2AX foci were counted using Imaris software (Fig. 5a). An average of 1.1 ± 0.8 DSBs were counted by 200 mGy, 3.3 ± 1.7 DSBs per cell nucleus by 400 mGy, 8.9 ± 3.1 DSBs per cell nucleus by 800 mGy and 18.4 ± 0.8 DSBs per cell nucleus by 1600 mGy. In parallel, γ-H2AX foci were counted visually by epifluorescence microscopy. An average number of 1.2 ± 0.3 DSBs per cell nucleus was counted for 200 mGy, 1.7 ± 0.4 DSBs were counted by 400 mGy, 3.17 ± 0.6 DSBs were counted by 800 mGy and 5.6 ± 1.9 DSBs per cell nuclei by 1600 mGy. Dose–response curves for γ-H2AX foci in irradiated WBCs obtained by confocal microscopy plus 3D reconstruction or by an epifluorescence microscope are shown in Fig. 5b.
Discussion
Genotoxicity is a wide field ranging from desired DNA DSB in malignant cells to kill them to unwanted effects of chemical compounds including drugs and physical influences such as irradiation and heat for example. To objectively estimate the genotoxicity of different origin, its extent can be quantified by counting the number of visible γ-H2AX foci. In a medical context (e.g., computer tomography), DNA DSBs may produce genetic instability and represent the most significant lesions after exposure to ionizing radiation.
However, previous approaches to study radiation-induced DSBs after diagnostic examinations neglected the 3D nature of the nucleus. In epifluorescence microscopy the entire field of the nucleus is simultaneously illuminated by light and visualized. The illumination of other parts of the specimen results in background noise, which affects the quality of the image (Nwaneshiudu et al. 2012). As a consequence γ-H2AX foci outside the focal point of the objective lens of the microscope are not taken into account.
In contrast, confocal microscopy plus 3D imaging enable a more realistic determination of number, size, and spatial arrangement of the γ-H2AX foci present. The significant difference in DSB counts per cell nucleus after irradiation between these two methods was shown in Fig. 4. Furthermore, the counting of DSBs/cell nucleus is independent of the person evaluating.
In the present study, we show the improved γ-H2AX assay on the basis of confocal microscopy and 3D image reconstructions. This improved assay does not simply identify foci in each Z-plane and count them on maximum intensity projection images as described elsewhere (Markova et al. 2007; Borras et al. 2015; Vasireddy et al. 2010). Projecting an object from a 3D volume to a 2D plane always results in information loss (Shihavuddin et al. 2017). Comparison of the values obtained by 3D reconstructed images with the numbers resulting from maximum intensity projection images showed that except for the non-irradiated samples the numbers were significantly higher (Fig. 3). Foci analysis by Rothkamm et al. of irradiated MRC-5 cells with 200 mGy after 15 min incubation time from maximum intensity projection images resulted in about 5 foci per cell nuclei (Rothkamm and Lobrich 2003). The value in the present study with 4.4 ± 1.9 foci per nuclei (Table 1), fully matches this result. The value at 200 mGy obtained by 3D reconstructed images was higher with 13.8 ± 1.6 foci per cell nuclei.
A further method of analysis, a so called pseudo 3D counting was described by Ivashkevich and collaborators (Ivashkevich et al. 2011). They showed that this method based on confocal microscopy and subsequent application of a mathematic algorithm (pseudo 3D counting) resulted in approximately the double number of DSBs compared with the conventional method. The method described in the current study, however, results in a 3.3–5.8 fold higher number of DSBs compared to epifluorescence microscopy and doesn’t require an algorithm to analyse overlapping objects in adjacent Z-planes.
The calculated ratio between confocal microscopy plus 3D reconstruction and epifluorescence microscopy revealed that the ratio is not uniform with increasing irradiation doses. Therefore, counted γ-H2AX foci by epifluorescence microscopy cannot be simply adjusted by multiplying the determined DSBs by a uniform factor. It displays all existing γ-H2AX foci and excludes overlapping by 3D reconstructed images.
In biological dosimetry, exact analysis of induced γ-H2AX foci is relevant. A discrepancy was observed in foci numbers in MRC-5 fibroblasts between counts made on maximum intensity projection images and those generated with Imaris/3D reconstruction. Foci analysis in WBC’s by the described method enables an improved study of the effects of ionizing radiation, with 2 to threefold higher number of DSBs compared to epifluorescence microscopy. Quantitatively similar results has been published for z-stack maximum projections of confocal sections (Ivashkevich et al. 2011). However, in contrast to the results presented herein the study of Ivashkevich et al. analyzed DSBs only in enriched lymphocytes obtained from whole blood. γ-H2AX signal is present in all nucleated white blood cells, however, the distribution of γ-H2AX signal may vary between nucleated blood cell types. The study of Ismail et al. showed 3 times higher level of γ-H2AX signal in B-lymphocytes than in unsorted WBC (Ismail et al. 2007). Hence, we would expect an increase in the number of DSB foci if only lymphocytes were analyzed with Imaris/3D reconstruction. Our method may increase the accuracy and sensitivity of identifying radiation mediated DNA damage after diagnostic examinations such as computed tomography. Our study shows a sigmoid dose–response curves in MRC-5 fibroblasts and in WBC’s as observed elsewhere [(Wojewodzka et al. 2015), unfitted data from Fig. 3b].
Taken together, these findings enable improved documentation and analysis of genotoxic radiation effects. Thus representing a new, sensitive and reliable research tool, which may increase the accuracy and sensitivity of identifying radiation mediated DNA damage in future patient care.
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Acknowledgements
The authors thank Ulrike Theobald, Fabian Blank and Philipp Kellmann for contributing excellent technical support, and Val Runge, Christof Granzow and Christoph Kempf for critically reading the manuscript. Images were acquired on equipment provided by the Microscopy Imaging Center (MIC) of the University of Bern.
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Ruprecht, N., Hungerbühler, M.N., Böhm, I.B. et al. Improved identification of DNA double strand breaks: γ-H2AX-epitope visualization by confocal microscopy and 3D reconstructed images. Radiat Environ Biophys 58, 295–302 (2019). https://doi.org/10.1007/s00411-019-00778-1
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DOI: https://doi.org/10.1007/s00411-019-00778-1