DNA breakage detection-fish (DBD-FISH): effect of unwinding time

DBD-FISH, an effective marker for detecting genotoxicity in buccal mucosa exfoliated cells of patients with oral cancer

Oral squamous cell carcinoma (OSCC) is characterized by increased genetic instability as an essential variable of event of neoplastic transformation. The aim of this study was to evaluate genomic instability in exfoliated cells from the buccal mucosa of patients with OSCC vs. the control group, using DNA Breakage Detection/Fluorescence In Situ hybridization (DBD-FISH). Exfoliated cells from the buccal mucosa were obtained from 38 patients with oral cancer (case group) and from 10 individuals without oral lesions (control group). DNA damage was evaluated by DBD-FISH using the whole-genome DNA probe and digital imaging analysis. Collaterally, HPV infection was determined utilizing the INNO-LiPA HPV kit. Patients with OSCC showed an increase in the hybridization signal five times more intense than that of the baseline level of DNA damage detected in control individuals. The best cutoff value for predicting oral squamous cell carcinoma was 67.46, and an Odds Ratio (OR) value of 87. HPV detection analysis revealed than one patient with OSCC (2.6%) was positive for HPV. All controls were negative HPV. In conclusion, DBD-FISH permitted the clear visualization of level high of DNA damage in the buccal epithelial cells of patients with OSSC respect to control group. Chromosome instability in oral mucosa may be an individual marker of malignant transformation in OSCC.

Mycobacterium tuberculosis promotes genomic instability in macrophages

BACKGROUND

Mycobacterium tuberculosis is an intracellular pathogen, which may either block cellular defensive mechanisms and survive inside the host cell or induce cell death. Several studies are still exploring the mechanisms involved in these processes.

OBJECTIVES

To evaluate the genomic instability of M. tuberculosis-infected macrophages and compare it with that of uninfected macrophages.

METHODS

We analysed the possible variations in the genomic instability of Mycobacterium-infected macrophages using the DNA breakage detection fluorescence in situ hybridisation (DBD-FISH) technique with a whole human genome DNA probe.

FINDINGS

Quantitative image analyses showed a significant increase in DNA damage in infected macrophages as compared with uninfected cells. DNA breaks were localised in nuclear membrane blebs, as confirmed with DNA fragmentation assay. Furthermore, a significant increase in micronuclei and nuclear abnormalities were observed in infected macrophages versus uninfected cells.

MAIN CONCLUSIONS

Genomic instability occurs during mycobacterial infection and these data may be seminal for future research on host cell DNA damage in M. tuberculosis infection.

Use of the DBD-FISH technique for detecting DNA breakage in response to high doses of X-rays

The aim of this study was to generate a dose-response curve using the DNA breakage detection-fluorescent in situ hybridization (DBD-FISH) test as a biomarker of initial genetic effects induced by high doses of X-rays. A dose-response curve was obtained by measuring the ex vivo responses to increasing doses (0-50 Gy) of X-rays in the peripheral blood lymphocytes of ten healthy donors. The overall dose-response curve was constructed using integrated density (ID; area × fluorescence intensity) as a measure of genetic damage induced by irradiation. The correlation coefficient was high (r = 0.934, b(0) = 10.408, and b(1) = 0.094). One-way ANOVA with the Student-Newman-Keuls test for multiple comparisons showed significant differences among the average ln ID values according to dose. Our results suggest the usefulness of the DBD-FISH technique for measuring intrinsic individual cellular radio sensitivity ex vivo.

Simultaneous labeling of single- and double-strand DNA breaks by DNA breakage detection-FISH (DBD-FISH)

DNA Breakage Detection-Fluorescence In Situ Hybridization (DBD-FISH) permits simultaneous and selective labeling of single- and double-strand DNA breaks in individual cells, either in the whole genome or within specific DNA sequences. In this technique, cells are embedded into agarose microgels, lysed and subjected to electrophoresis under nondenaturing conditions. Subsequently, the produced "comets" are exposed to a controlled denaturation step which transforms DNA breaks into single-stranded DNA regions, detected by hybridization with whole genome fluorescent probes or the probes to specific DNA sequences. This makes possible a targeted analysis of various chromatin areas for the presence of DNA breaks. The migration length of the DBD-FISH signal is proportional to the number of double strand breaks, whereas its fluorescence intensity depends on numbers of single-strand breaks.The detailed protocol for detection of two types of DNA breaks produced by ionizing radiation is presented. The technique can be used to determine intragenomic and intercellular heterogeneity in the induction and repair of DNA damage.

FISH glossary: an overview of the fluorescence in situ hybridization technique

The introduction of FISH (fluorescence in situ hybridization) marked the beginning of a new era for the study of chromosome structure and function. As a combined molecular and cytological approach, the major advantage of this visually appealing technique resides in its unique ability to provide an intermediate degree of resolution between DNA analysis and chromosomal investigations while retaining information at the single-cell level. Used to support large-scale mapping and sequencing efforts related to the human genome project, FISH accuracy and versatility were subsequently capitalized on in biological and medical research, providing a wealth of diverse applications and FISH-based diagnostic assays. The diversification of the original FISH protocol into the impressive number of procedures available these days has been promoted throughout the years by a number of interconnected factors: the improvement in sensitivity, specificity and resolution, together with the advances in the fields of fluorescence microscopy and digital imaging, and the growing availability of genomic and bioinformatic resources. By assembling in a glossary format many of the "acronymed" FISH applications published so far, this review intends to celebrate the ability of FISH to re-invent itself and thus remain at the forefront of biomedical research.

Two essential modifications strongly improve the performance of the Fast Micromethod to identify DNA single- and double-strand breaks

To identify DNA single- or double-strand breaks, various techniques have been described. One of them, the Fast Micromethod, is an easy-to-perform 96-well microplate assay. Cells treated with chemicals are loaded with the fluorescent dye PicoGreen, which binds to double-stranded DNA with a high specificity. Following DNA denaturation in an alkaline buffer, DNA unwinding occurs and PicoGreen is released. The amount of PicoGreen released over a certain period of time reflects the extent of DNA damage. To maximize the throughput of the procedure and to minimize DNA damage due to the analytical procedures used, the Fast Micromethod was improved in two essential points. First, the very time-consuming cell-counting was substituted by a simple protein measurement. Second, the cell lysis step was omitted. By introducing the two above mentioned modifications, a high number of samples can now be analyzed within a much shorter period of time.

The comet assay in male reproductive toxicology

Due to our lifestyle and the environment we live in, we are constantly confronted with genotoxic or potentially genotoxic compounds. These toxins can cause DNA damage to our cells, leading to an increase in mutations. Sometimes such mutations could give rise to cancer in somatic cells. However, when germ cells are affected, then the damage could also have an effect on the next and successive generations. A rapid, sensitive and reliable method to detect DNA damage and assess the integrity of the genome within single cells is that of the comet or single-cell gel electrophoresis assay. The present communication gives an overview of the use of the comet assay utilising sperm or testicular cells in reproductive toxicology. This includes consideration of damage assessed by protocol modification, cryopreservation vs the use of fresh sperm, viability and statistics. It further focuses on in vivo and in vitro comet assay studies with sperm and a comparison of this assay with other assays measuring germ cell genotoxicity. As most of the de novo structural aberrations occur in sperm and spermatogenesis is functional from puberty to old age, whereas female germ cells are more complicated to obtain, the examination of male germ cells seems to be an easier and logical choice for research and testing in reproductive toxicology. In addition, the importance of such an assay for the paternal impact of genetic damage in offspring is undisputed. As there is a growing interest in the evaluation of genotoxins in male germ cells, the comet assay allows in vitro and in vivo assessments of various environmental and lifestyle genotoxins to be reliably determined.

Interstitial telomeric DNA sequences of Chinese hamster cells are hypersensitive to nitric oxide damage, and DNA-PKcs has a specific local role in its repair

The DNA breakage detection-fluorescence in situ hybridization (DBD-FISH) procedure was used to analyze DNA single-strand breaks (SSBs) and alkali-labile sites induced by exposure to the nitric oxide (NO) donors sodium nitroprusside (SNP) and 3-morpholinosydnomine hydrochloride (SIN-1) in the whole genome and in long interstitial telomeric repeat sequence (ITRS) blocks from Chinese hamster cells. The relative density of DNA damage generated in the ITRS by X-rays was similar to that induced in the genome overall, whereas it was 1.7 times higher when the alkylating agent MNNG was assayed. Nevertheless, after SNP or SIN-1 treatment, ITRSs proved to be 2.8 and 2.7 times relatively more damaged, respectively, than the whole genome. When the DNA-dependent protein kinase catalytic subunit (DNA-PKcs) was not active, as in XR-C1 mutant cells, the repair kinetics in the whole genome did not differ from that in the parental cell line with X-ray or SNP exposure. However, whereas the SSBs and alkali-labile sites induced in the ITRS by X-rays exhibited rejoining kinetics similar to that of the parental cell line, the damage induced by SNP was more slowly rejoined. This implies a role for DNA-PKcs in the repair of DNA damage induced by NO, especially in ITRSs. The results demonstrated intragenomic heterogeneity of NO-induced DNA damage and repair; there was a higher density of DNA damage in the ITRS blocks, possibly because of their guanine richness. This suggests that a parallel process may occur in the terminal telomeres, which has implications for premature aging and neoplastic development by chronic NO exposure in vivo.

Radiation-induced DNA breaks in different human satellite DNA sequence areas, analyzed by DNA breakage detection-fluorescence in situ hybridization

Human blood leukocytes were exposed to X rays to analyze the initial level of DNA breakage induced within different satellite DNA sequence areas and telomeres, using the DNA breakage detection-FISH procedure. The satellite DNA families analyzed comprised alphoid sequences, satellite 1, and 5-bp classical satellite DNA sequences from chromosome 1 (D1Z1 locus), from chromosome 9 (D9Z3 locus), and from the Y chromosome (DYZ1 locus). Since the control hybridization signal was quite different in each of the DNA targets, the relative increase in whole fluorescence intensity with respect to unirradiated controls was the parameter used for comparison. Irradiation of nucleoids obtained after protein removal demonstrated that the alkaline unwinding solution generates around half the amount of signal when breaks are present in the 5-bp classical DNA satellites as when the same numbers of breaks are present the genome overall, whereas the signal is slightly stronger when the breaks are within the alphoids or satellite 1 sequences. After correction for differences in sensitivity to the alkaline unwinding-renaturation, DNA housed in chromatin corresponding to 5-bp classical satellites proved to be more sensitive to breakage than the overall genome, whereas DNA in the chromatin corresponding to alphoids or satellite 1 showed a sensitivity similar to that of the whole genome. The minimum detectable dose was 0.1 Gy for the whole genome, 0.2 Gy for alphoids and satellite 1, and 0.4 Gy for the 5-bp classical satellites. Telomeric DNA sequences appeared to be maximally labeled in unirradiated cells. Thus telomeric ends behave like DNA breaks, constituting a source of background in alkaline unwinding assays.

High frequency of constitutive alkali-labile sites in mouse major satellite DNA, detected by DNA breakage detection-fluorescence in situ hybridization

DNA breakage detection-fluorescence in situ hybridization (DBD-FISH) is a new procedure for detecting and quantifying DNA breaks and alkali-labile sites in single cells. Cells trapped within an agarose matrix are deproteinized and treated with an alkaline unwinding solution that transforms DNA breaks and alkali-labile sites into single-strand DNA (ssDNA) motifs starting from the end of the break. These ssDNA motifs are susceptible to being hybridized with whole genome or specific DNA probes, and detected using current FISH procedures. As DNA breaks increase in a target region, more ssDNA is produced and more DNA probe hybridizes, thus increasing the FISH signal, which may be captured and analyzed using a digital image analysis system. This increase can be reflected in the surface area, mean and whole fluorescence intensity of the signal. When intact mouse splenocytes were processed with this technique using a whole genome probe, a very strong background signal was evident when compared with human blood leukocytes. In fact, when using 0.03M NaOH as the alkaline unwinding solution at 22 degrees C for 2.5min, the whole fluorescence intensity from mice cells was 50 times higher than that from human cells, thus suggesting the existence of a high frequency of constitutive alkali-labile sites in the DNA from mouse cells. Furthermore, when alkaline unwound mouse cells were simultaneously hybridized with the whole genome probe (FITC-revealed, green) and a major satellite DNA probe (Cy-3-labeled, red) both signals appeared co-localized. This result demonstrates that the high frequency of constitutive alkali-labile sites detected in the mouse genome is mainly located in the major satellite DNA sequences, resembling the findings from human 5bp classical satellite DNA sequences.

DBD-fish on neutral comets: simultaneous analysis of DNA single- and double-strand breaks in individual cells

Humanblood leukocytes exposed to X-rays were immersed in an agarose microgel on a slide, extensively deproteinized, and electrophoresed under neutral conditions. Following this single-cell gel electrophoresis assay, characteristics of DNA migration (i.e., area of the comet) are related to the DNA double-strand breaks (dsbs) yield. After electrophoresis, comets were briefly incubated in an alkaline unwinding solution, transforming DNA breaks and alkali-labile sites into restricted single-stranded DNA (ssDNA) motifs. These motifs behave as target sites for hybridization with a whole genome probe, following the DNA breakage detection-fluorescence in situ hybridization (DBD-FISH) procedure. As DNA breakage increases with dose, more ssDNA is produced in the comet by the alkali and more DNA probe hybridizes, resulting in an increase in the mean fluorescence intensity. Since radiation-induced DNA single-strand breaks (ssbs) are far more frequent than dsbs, the mean fluorescence intensity of the DBD-FISH signal from the comet is related to the ssb level, whereas the surface area of the same comet signal is indicative of the dsb yield. Thus, both DNA break types may be simultaneously analyzed in the same cell. This was confirmed in a repair assay performing the DBD-FISH on neutral comets from a human cell line defective in the repair of dsbs. Otherwise, treatment with hydrogen peroxide, a main inducer of ssbs, increased the mean fluorescence intensity, but not the surface, of X-ray-exposed human leukocytes.