Limitations of the in vitro repair synthesis assay for probing the role of DNA repair in platinum resistance.

Several studies have implicated enhanced DNA repair in acquired platinum resistance. To better understand the mechanism of increased repair we have employed an in vitro assay using cell-free extracts from platinum sensitive and resistant murine and human cell lines. Since the platinum resistant murine cell lines used in our previous studies had shown increased repair of diaminocyclohexane(dach)-Pt-DNA adducts while one of the resistant human cell lines did not, we have measured in vitro repair synthesis on DNA damaged by (d,l)-trans-1,2-diaminocyclohexanedichloroplatinum(II) (PtCl2(dach)). The results of this assay were strongly dependent on the method used to calculate repair synthesis activity and appeared to disagree with previous estimates of repair activity in these cell lines. By one method of calculation the in vitro repair synthesis assay underestimated the ratio of repair activities in the resistant versus the sensitive murine cell lines, while by the other method the in vitro assay overestimated the ratio of repair activities in the resistant versus the sensitive human cell lines.     

Rapid assessment of repair of ultraviolet DNA damage with a modified host-cell reactivation assay using a luciferase reporter gene and correlation with polymorphisms of DNA repair genes in normal human lymphocytes

As DNA repair plays an important role in genetic susceptibility to cancer, assessment of the DNA repair phenotype is critical for molecular epidemiological studies of cancer. In this report, we compared use of the luciferase (luc) reporter gene in a host-cell reactivation (HCR) (LUC) assay of repair of ultraviolet (UV) damage to DNA to use of the chloramphenicol (cat) gene-based HCR (CAT) assay we used previously for case-control studies. We performed both the assays on cryopreserved lymphocytes from 102 healthy non-Hispanic white subjects. There was a close correlation between DNA repair capacity (DRC) as measured by the LUC and CAT assays. Although these two assays had similar variation, the LUC assay was faster and more sensitive. We also analyzed the relationship between DRC and the subjects' previously determined genotypes for four polymorphisms of two nucleotide-excision repair (NER) genes (in intron 9 of xeroderma pigmentosum (XP) C and exons 6, 10 and 23 of XPD) and one polymorphism of a base-excision repair gene in exon 10 of X-ray complementing group 1 (XRCC1). The DRC was significantly lower in subjects homozygous for one or more polymorphisms of the two NER genes than in subjects with other genotypes (P=0.010). In contrast, the polymorphic XRCC1 allele had no significant effect on DRC. These results suggest that the post-UV LUC assay measures NER phenotype and that polymorphisms of XPC and XPD genes modulate DRC. For population studies of the DNA repair phenotype, many samples need to be evaluated, and so the LUC assay has several advantages over the CAT assay: the LUC assay was more sensitive, had less variation, was not radioactive, was easier to perform, and required fewer cryopreserved cells. These features make the LUC-based HCR assay suitable for molecular epidemiological studies.     

Use of the single cell gel electrophoresis/comet assay for detecting DNA damage in aquatic (marine and freshwater) animals

The comet assay is a rapid, sensitive and inexpensive method for measuring DNA strand breaks. The comet assay has advantages over other DNA damage methods, such as sister chromatid exchange, alkali elution and micronucleus assay, because of its high sensitivity and that DNA strand breaks are determined in individual cells. This review describes a number of studies that used the comet assay to determine DNA strand breaks in aquatic animals exposed to genotoxicants both in vitro and in vivo, including assessment of DNA damage in aquatic animals collected from contaminated sites. One difficulty of using the comet assay in environmental work is that of comparing results from studies that used different methods, such as empirical scoring or comet tail lengths. There seems to be a consensus in more recent studies to use both the intensity of the tail and the length of the tail, i.e. DNA tail moment, percentage of DNA in the tail. The comet assay has been used to assess DNA repair and apoptosis in aquatic animals and modifications of the comet assay have allowed the detection of specific DNA lesions. There have been some recent studies to link DNA strand breaks in aquatic animals to effects on the immune system, reproduction, growth, and population dynamics. Further work is required before the comet assay can be used as a standard bio-indicator in aquatic environments, including standardization of methods (such as ASTM method E2186-02a) and measurements.     

DMBA induced DNA damage and repair in mammary epithelial cells in vitro measured by a nick translation assay

A new E. coli DNA polymerase I directed nick translation assay was used for measuring 7,12-dimethylbenz[a]anthracene-induced in situ DNA damage and repair in mouse mammary epithelial cells in monolayer culture. The nick translation assay was capable of detecting a DMBA-dose dependent significant increase of DNA damage, and the same assay also allowed monitoring of the DNA repair activity provoked by DMBA treatment of the epithelial cells. This relatively simple method thus provides a rapid assay for carcinogen-induced in situ DNA damage and repair in an epithelial cell tumorigenic system.     

Influence of mus201 and mus308 mutations of Drosophila melanogaster on the genotoxicity of model chemicals in somatic cells in vivo measured with the comet assay

To check the possibilities of the recently developed comet assay, to be used in mechanistic studies in Drosophila melanogaster, neuroblast cells of third instar larvae are used to analyse in vivo, the effect of two repair deficient mutations: mus201, deficient on nucleotide excision repair, and mus308, deficient in a mechanism of damage bypass, on the genotoxicity of methyl methanesulphonate (MMS), ethyl methanesulphonate (EMS) and N-ethyl-N-nitrosourea (ENU). The obtained results reveal: (1) MMS-induced breaks are most probably consequence of N-alkylation damage mediated abasic (AP) site breakage; (2) MMS and at least part of the EMS induced damage leading to DNA strand breaks are efficiently repaired by the nucleotide excision repair mechanism; (3) ENU and part of EMS induced damage need a functional Mus308 protein to be processed, otherwise they can lead to DNA strand breaks. In addition, the results of this work confirm the validity of neuroblast cells to conduct the comet assay, and the usefulness of this assay in in vivo mechanistic studies related to DNA repair in D. melanogaster.     

Microplate enzyme-linked immunosorbent assay for the detection of primary DNA alterations based on the interaction with UvrA/UvrB

An enzyme-linked microplate immunoassay for the analysis of primary DNA lesions is described. The assay principle is based on the interaction of the bacterial DNA repair proteins UvrA and UvrB with DNA and on the immunodetection of UvrB forming a stable complex with covalently modified nucleotides. Using this technique we were able to detect damages in genomic DNA induced by uv light and by several different genotoxic agents. The detection sensitivity of the method reaches down to the nanomolar range of the mutagenic compound depending on the type of the DNA alteration. The method might be used in automated high-throughput studies.     

Assays for 8-hydroxy-2'-deoxyguanosine: a biomarker of in vivo oxidative DNA damage.

HPLC with electrochemical detection (HPLC-EC) is a highly sensitive and a selective method for detecting 8-hydroxy-2'-deoxyguanosine (oh8dG), a biomarker of oxidative DNA damage that is formed from hydroxyl radical attack of guanine residues in DNA. We propose that the noninvasive measurement of oh8dG in urine can be used to estimate in vivo oxidative damage. Application of this assay to urine samples obtained from rats of different ages and various species provide examples of the utility of this assay. The measurement of steady-state levels of oh8dG in DNA combined with the urinary excretion rates of oh8dG and oh8Gua, offer a powerful approach for estimating oxidative DNA damage and its repair. This method will be useful for studies designed to investigate the relationship of oxidative stress in DNA damage and the role of this damage in aging and cancer.     

Detection of oxaliplatin-induced DNA crosslinks in vitro and in cancer patients using the alkaline comet assay

Oxaliplatin is frequently used in the therapy of cancer. In DNA, oxaliplatin induces, like cisplatin, the formation of crosslinks, which are commonly accepted as being responsible for the cytotoxicity of platinum agents. The detection of oxaliplatin-induced DNA crosslink formation and repair could be a good measure of assessing how a patient is responding to the agent. In this study, we used a validated modification of the alkaline comet assay for detecting the presence of these crosslinks in vitro and in cancer patients. The H460 tumour cell line was treated in vitro with a range of oxaliplatin and cisplatin doses, and the subsequent crosslink formation and repair compared between the two agents. In addition, lymphocytes from cancer patients undergoing oxaliplatin-based chemotherapy were assayed for the formation and repair of oxaliplatin-induced crosslinks. A dose-response was observed in the in vitro samples, with cisplatin producing more crosslinks than oxaliplatin at equimolar concentrations and lesions induced by both agents showing different repair efficiencies. Furthermore, evidence of crosslink formation and repair was observed in the peripheral blood lymphocytes of all cancer patients studied, along with the detection of interindividual variability in crosslink formation and repair efficiencies. To the best of our knowledge, this is the first time that oxaliplatin DNA crosslinks have been detected either in vitro or in patient samples using the alkaline comet assay. Due to its sensitivity, rapidity, small cell sample and low cost, the alkaline comet assay is a good method for the detection of oxaliplatin-induced crosslinks and their subsequent repair and, in future clinical studies, could prove to be a valuable tool in assessing/predicting a patient's response to chemotherapy.     

Modification of the alkaline Comet assay to allow simultaneous evaluation of mitomycin C-induced DNA cross-link damage and repair of specific DNA sequences in RT4 cells

The alkaline Comet assay is a simple, sensitive method for measuring the extent of DNA strand breaks in individual cells. Several modifications to the original assay have been developed to increase its applications. One such modification allows the measurement of DNA cross-links by assessing the relative reduction in DNA migration induced by a strand-breaking agent. Another modification includes the application of fluorescent in situ hybridisation (FISH) to investigate the localisation of specific gene domains within a cell. Although several studies have used these approaches separately, no report to date has combined these two versions of the Comet assay. The current study describes the modification of the Comet assay, to allow both measurement of mitomycin C (MMC)-induced cross-links and the subsequent application of FISH to study repair in the TP53 gene region. RT4 human bladder cancer cells were treated with 0, 5, 50 and 200 microg/ml MMC to study dose response, whilst for cross-link repair studies, they were treated with 50 microg/ml MMC and allowed to repair for up to 24 h. A clear dose response to MMC was displayed, demonstrable by a marked reduction in DNA migration, whilst repair studies showed that MMC-induced cross-links take at least 24 h to repair fully in RT4 cells. For Comet-FISH experiments, the number and location of TP53 hybridisation spots was also recorded for each cell. In dose response experiments, the number of spots per cell, and per Comet tail, decreased as MMC dose increased. In repair experiments, the number of spots, particularly in the Comet tail, increased as repair time increased. Furthermore, our results suggest that repair of the TP53 gene region is most rapid within the first 4 h following MMC treatment. We conclude that the novel experimental protocol presented here has considerable potential in evaluating DNA damage and sequence-related repair responses to cross-linking agents.     

DNA断裂检测方法──单细胞凝胶电泳法

单细胞凝胶电泳(single cell gel electrophoresis assay,SCGE)也叫彗星试验(comet assay),是一种快速、敏感、简便、廉价的检测单个哺乳动物细胞DNA断裂的技术,目前已用于检测氧化、紫外线和电离辐射引起的损伤,以及三氯乙烷、丙烯酰胺等化学物及老化、吸烟所致损害的研究.文章介绍SCGE的发展、检测分析方法、原理及其在DNA损伤与修复、生物监测、遗传毒理研究、肿瘤治疗方案优化和疗效研究方面的应用前景．     

Human nucleotide excision repair in vitro: repair of pyrimidine dimers, psoralen and cisplatin adducts by HeLa cell-free extract.

We searched for nucleotide excision repair in human cell-free extracts using two assays: damage-specific incision of DNA (the nicking assay) and damage-stimulated DNA synthesis (the repair synthesis assay). HeLa cell-free extract prepared by the method of Manley et al. (1980) has a weak nicking activity on UV irradiated DNA and the nicking is only slightly reduced when pyrimidine dimers are eliminated from the substrate by DNA photolyase. In contrast to the nicking assay, the extract gives a strong signal with UV irradiated substrate in the repair synthesis assay. The repair synthesis activity is ATP dependent and is reduced by about 50% by prior treatment of the substrate with DNA photolyase indicating that this fraction of repair synthesis is due to removal of pyrimidine dimers by nucleotide excision. Psoralen and cisplatin adducts which are known to be removed by nucleotide excision repair also elicited repair synthesis activity 5-10 fold above the background synthesis. When M13RF DNA containing a uniquely placed psoralen adduct was used in the reaction, complete repair was achieved in a fraction of molecules as evidenced by the restoration of psoralen inactivated KpnI restriction site. This activity is absent in xeroderma pigmentosum group A cells. We conclude that our cell-free extract contains the human nucleotide excision repair enzyme activity.     

Single cell gel electrophoresis assay (comet assay): its importance in human biology

The estimation of genetic instability by direct extent of DNA damage and repair is an important aspect of studies on mutagenesis, carcinogenesis, aging and evolution. Different methods have been introduced from time to time in an effort to meet this need. Single cell gel electrophoresis (SCGE) assay is a new, simple and sensitive method of evaluating DNA damage and repair at individual cell level. This assay can be performed on extremely small number of cells and results can be obtained within a relatively short time. The SCGE assay has the potential to play an important role not only in the understanding of some of the fundamental aspects of human biology but also can be helpful in many practical ways. For reprint requests.     

The comet assay: a method to measure DNA damage in individual cells

We present a procedure for the comet assay, a gel electrophoresis-based method that can be used to measure DNA damage in individual eukaryotic cells. It is versatile, relatively simple to perform and sensitive. Although most investigations make use of its ability to measure DNA single-strand breaks, modifications to the method allow detection of DNA double-strand breaks, cross-links, base damage and apoptotic nuclei. The limit of sensitivity is approximately 50 strand breaks per diploid mammalian cell. DNA damage and its repair in single-cell suspensions prepared from yeast, protozoa, plants, invertebrates and mammals can also be studied using this assay. Originally developed to measure variation in DNA damage and repair capacity within a population of mammalian cells, applications of the comet assay now range from human and sentinel animal biomonitoring (e.g., DNA damage in earthworms crawling through toxic waste sites) to measurement of DNA damage in specific genomic sequences. This protocol can be completed in fewer than 24 h.     

Optimization of the alkaline comet assay for easy repair capacity quantification of oxidative DNA damage in PBMC from human volunteers using aphidicolin block

Assessment of DNA repair capacity (DRC) upon ex vivo challenge of peripheral blood mononuclear cells (PBMC) with oxidative damage inducing agents, as evaluated by the comet assay, is widely used as biomarker to assess the antioxidant status in human studies. Here, the alkaline comet assay was now optimized for easy and time saving detection of repair capacity upon oxidative stress-induced DNA damage using the DNA polymerase inhibitor aphidicolin (APC) to block repair of hydrogen peroxide (H₂O₂) induced DNA damage. Addition of a DMSO-containing DNA damage stop solution was found suitable to replace washing steps for H₂O₂ removal before APC block. Cell treatment with APC at 6 μM did not impact baseline DNA damage but could reliably block DNA repair after H₂O₂ challenge in both fresh and cryopreserved samples thus omitting the use of a starting time point control. Under the conditions used, frozen cells, with or without an additional 4 h rest, showed the same repair capacity as their fresh counterpart. The intra assay coefficient of variation (CV) was 3.3%. To provide proof of principle, the modified assay was applied to cryopreserved PBMC from 19 participants of a short-term Brassica diet intervention study investigating potential health promoting effects of the food intervention. Then, a 33% increase in DRC (p ≤ 0.01) could be shown in samples after intervention (mean ± SD: 5.82 ± 1) as compared to baseline (mean ± SD: 4.38 ± 1.21). Individual samples from baseline and intervention showed an inter-individual CV of 27.65% (baseline) and 17.26% (intervention). Taken together this modified comet assay protocol allows the facilitated detection of DNA repair in fresh or cryopreserved human PBMC samples with a good sensitivity and reliability and could be useful in human studies addressing the antioxidant status and repair capacity of PBMC.     

A modified fluorimetric neutral filter elution method for analyzing radiation-induced double strand break and repair

Neutral filter elution assay is one of the methods used for detection of DNA double strand breaks (DSBs). However, it is laborious, expensive, and hazardous (radiolabeled precursors for DSB detection and scintillation counter for quantification), making it a less preferred method for DSB detection. In the present study, an attempt was made to improve the existing neutral filter elution assay by making use of fluorescent dye (PicoGreen) and microfiltration assembly for eluting the fragmented DNA, thereby reducing the cost and time required for the assay. We studied the effect of dye dilution, pH conditions, and cell number as a part of method standardization. X-ray dose–response and repair kinetics in lymphocytes as well as cell lines were studied for validating the sensitivity of the assay. A linear dose–response relationship for DSBs was observed at a cell number of 4 × 10⁵ cells, a dye dilution of 500-fold, and at pH 10. Repair kinetics revealed a time-dependent repair of DSBs up to 360 min of posttreatment, indicating its usefulness in DSB repair studies. In conclusion, the present modified method is more efficient (in terms of cell number), cost effective, less time-consuming, and less hazardous compared to the existing method.     

Evaluation of DNA double strand breaks repair efficiency in head and neck cancer

Head and neck cancers (head and neck squamous cell carcinomas [HNSCC]) are a heterogeneous group of neoplasms with varying presenting symptoms, treatment, and expected outcome. There is a need to find an effective way of its treatment at the molecular level. Thus, we should identify the mechanism of cancer cell response to damaging agents' activity, especially at DNA level. Our major goal was to evaluate the efficacy of DNA double strand breaks (DSBs) repair in HTB-43 and SCC-25 cancer cell lines as well as lymphocytes taken from HNSCC patients and healthy donors. The DNA repair efficiency was measured by neutral comet assay as well as extrachromosomal assay for DNA DSBs repair (TAK assay). We determined the levels of two main pathways of DNA DSBs-nonhomologous end joining (NHEJ) and homologous recombination repair (HRR). Neutral comet assay was used for evaluation of DNA DSBs repair after treatment with genotoxic agents. DNA DSBs induced by gamma radiation were repaired slower in lymphocytes from HNSCC patients than in lymphocytes from healthy controls. HTB-43 and SCC-25 cancer cell lines have higher efficacy of NHEJ and HRR than lymphocytes taken from patients as well as control subjects. Our results confirm the necessity of further studies on the mechanisms of DNA DSBs repair to provide insight into the molecular basis of head and neck cancer, which will allow us to improve methods of HNSCC treatment.     

New Application of the Comet Assay: Chromosome�CComet Assay

The comet assay is a well-established, simple, versatile, visual, rapid, and sensitive tool used extensively to assess DNA damage and DNA repair quantitatively and qualitatively in single cells. The comet assay is most frequently used to analyze white blood cells or lymphocytes in human biomonitoring studies, although other cell types have been examined, including buccal, nasal, epithelial, and placental cells and even spermatozoa. This study was conducted to design a protocol that can be used to generate comets in subnuclear units, such as chromosomes. The new technique is based on the chromosome isolation protocols currently used for whole chromosome mounting in electron microscopy, coupled to the alkaline variant of the comet assay, to detect DNA damage. The results show that migrant DNA fragments can be visualized in whole nuclei and isolated chromosomes and that they exhibit patterns of DNA migration that depend on the level of DNA damage produced. This protocol has great potential for the highly reproducible study of DNA damage and repair in specific chromosomal domains.     

125IdUrd-induced chromosome fragments, assayed by premature chromosome condensation, and DNA double-strand breaks have similar repair kinetics in G1-phase CHO-cells

The effect of 125I-decay on cell lethality, and induction of chromosome and DNA damage, was studied in synchronous non-cycling, G1-phase CHO-cells. For this purpose a population of mitotic cells was allowed to divide and progress through S-phase in the presence of 125IdUrd. Cells were subsequently transferred to conditioned medium (C-med) obtained from plateau-phase cultures that allowed cells to divide and accumulate in G1-phase in a non-cycling state. To accumulate 125I-induced damage, cells were kept frozen at -80 degrees C. Freezing was carried out using a new method that optimally preserves cell integrity. After various times of cold storage, cells were thawed and assayed for survival, DNA and chromosome damage, either immediately or after various times in C-med. Neutral filter elution was used to assay repair of DNA double-strand breaks (dsbs), and premature chromosome condensation was used to assay repair of chromosome fragments and induction of ring chromosomes. The results indicate very little repair at the cell survival level (repair of PLD). At the DNA level an efficient repair of DNA dsbs was observed, with kinetics similar to those observed after exposure to X-rays. At the chromosome level a fast repair of prematurely condensed chromosome fragment was observed, with a concomitant increase in the number of ring chromosomes induced. The repair kinetics of chromosome fragments and DNA dsbs were very similar, suggesting that DNA dsbs may underlie chromosome fragmentation.