Repair of ultraviolet B and singlet oxygen-induced DNA damage in xeroderma pigmentosum cells.

Ultraviolet B (UVB) (290-320 nm) is capable of damaging the DNA molecule directly by generating predominantly pyrimidine dimers. UVA (320-400 nm) does not alter the DNA molecule directly. However, when it is absorbed by cellular photosensitizers, it can damage the DNA molecule indirectly, e.g., by mediation of singlet oxygen, generating predominantly 8-hydroxyguanine. These indirect effects have been implicated in the mutagenic, genotoxic, and carcinogenic effects of UVA. To study the processing of directly and indirectly UV-induced DNA damage in intact, DNA-repair-proficient and -deficient human cells, we used the replicating plasmid pRSVcat, either irradiated with up to 10 kJ/m2 UVB or treated with the photosensitizer methylene blue plus visible light (which generates singlet oxygen). These treated plasmids were introduced into lymphoblast lines from normal donors or from patients with xeroderma pigmentosum (XP) complementation groups A, C, D, E, and variant. DNA repair was assessed by measuring activity of reactivated chloramphenicol-acetyl-transferase enzyme, encoded by the plasmid's cat gene, in cell extracts after 3 d. As expected, the repair of UVB-induced DNA damage was reduced in all XP cell lines, and the degree varied with the complementation group. XP-A, -D, -E, and -variant cells were normally efficient in the repair of singlet oxygen-induced DNA damage. Only three of four XP-C cell lines showed a markedly reduced repair of these lesions. This indicates differential DNA-repair pathways for directly and indirectly UV-induced DNA damage in human cells and suggests that both may be affected in XP-C.

Alterations of DNA repair in melanoma cell lines resistant to cisplatin, fotemustine, or etoposide.

Resistance to chemotherapy is a common phenomenon in malignant melanoma. In order to assess the role of altered DNA repair in chemoresistant melanoma, we investigated different DNA repair pathways in one parental human melanoma line (MeWo) and in sublines of MeWo selected in vitro for drug resistance against four commonly used drugs (cisplatin, fotemustine, etoposide, and vindesine). Host cell reactivation assays with the plasmid pRSVcat were used to assess processing of different DNA lesions. With ultraviolet-irradiated plasmids, no significant differences were found, indicating a normal (nucleotide excision) repair of DNA photoproducts. With singlet oxygen-treated plasmid, the fotemustine- and cisplatin-resistant lines exhibited a significantly increased (base excision) repair of oxidative DNA damage. With fotemustine-treated plasmid, the fotemustine-resistant subline did not exhibit an increased repair of directly fotemustine-induced DNA damage. Similar results were obtained with cisplatin-induced DNA crosslinks in the cisplatin-resistant line. The fotemustine- and etoposide-resistant sublines have been shown to exhibit a reduced expression of genes involved in DNA mismatch repair. We used a "host cell microsatellite stability assay" with the plasmid pZCA29 and found a 2.0-fold to 2.5-fold increase of microsatellite frameshift mutations (p < or = 0.002) in the two resistant sublines. This indicates microsatellite instability, the hallmark of an impaired DNA mismatch repair. The increased repair of oxidative DNA damage might mediate an increased chemoresistance through an improved repair of drug-induced DNA damage. In contrast, a reduced DNA mismatch repair might confer resistance by preventing futile degradation of newly synthesized DNA opposite alkylation damage, or by an inability to detect such damage and subsequent inability to undergo DNA-damage-induced apoptosis.

Hypermutable ligation of plasmid DNA ends in cells from patients with Werner syndrome.

Werner Syndrome is a rare autosomal recessive disorder characterized by an increased cancer risk and by symptoms suggestive of premature aging. Cells from these patients demonstrate a typical pattern of chromosomal instability and a spontaneous hypermutability with a high rate of unusually large deletions. We have studied the in vivo DNA ligation in three lymphoblast cell lines from Werner syndrome patients and three from normal donors. In our host cell ligation assay we transfected linearized plasmid pZ189 and measured the amount of plasmid DNA ends rejoined by these host cells as the ability of the recovered plasmid to transform bacteria. A mutagenesis marker gene close to the ligation site allowed screening for mutations. Subsequent mutation analysis provided information about the accuracy of the ligation process. The cells from Werner syndrome patients were as effective as normal cells in ligating DNA ends. However, mutation analysis revealed that the three Werner syndrome cell lines introduced 2.4-4.6 times more mutations (p < 0.001) than the normal cell lines during ligation of the DNA ends: the mutation rates were 69.4, 97.2, and 58.7%, as compared to 23.6, 21.7, and 24.4% in the normal cell lines. These increased mutation frequencies in plasmids ligated during passage through Werner syndrome cells were mainly due to a significant (p < 0.001) increase in deletions. This error-prone DNA ligation might be responsible for the spontaneous hypermutability and the genomic instability in Werner syndrome cells and related to the apparently accelerated aging and high cancer risk in affected patients.

Specific autologous anti-melanoma T cell response in vitro using monocyte-derived dendritic cells.

Dendritic cells (DC) are antigen-presenting cells initiating primary and secondary immune responses. Since malignant tumors are able to escape immunologic control, DC might be prime candidates to activate the immune system against tumor cells. In an autologous system, a dynamic interaction among monocyte-derived DC (MoDC), T lymphocytes, and tumor cells obtained from melanoma patients could be noted. MoDC were generated from blood monocytes in the presence of GM-CSF, IL-4, and IFN-gamma. T cells were isolated either from peripheral blood or from lymph nodes. Melanoma cells were harvested from surgically removed tumor metastases. They were then gamma-irradiated and co-cultured with autologous MoDC and T lymphocytes. After 5 days, the lymphocytes showed a high proliferative activity and the majority of them were CD8-positive. In five cases tested, they revealed a high cytotoxic activity resulting in apoptosis of tumor cells. These findings suggest that MoDC are capable of initiating an effective specific anti-tumor response in a strictly autologous mixed lymphocyte tumor culture (MLTC), even though tumor-specific antigens had not been individually defined. Therefore (I) whole melanoma cells can serve as a source of antigen, (II) monocyte-derived dendritic cells may process and present melanoma-specific antigens resulting in a strong lymphocyte proliferation, (III) the majority of responding T lymphocytes are CD8-positive, and (IV) an acquired cytotoxic response eventually leads to apoptosis of the melanoma cells. The reaction demonstrated here permits to in vitro and quantitatively monitoring the effect of T cell directed immunotherapies such as the adoptive immunotherapy of tumors.

Processing of directly and indirectly ultraviolet-induced DNA damage in human cells.

Mutations caused by ultraviolet (UV)-induced DNA damage represent the initial genetic changes in the tumorigenesis of UV-induced skin cancer. Different wavelengths of UV radiation cause different kinds of DNA damage and mutations. UVB (290-320 nm) generates pyrimidine dimers by direct excitation of the DNA molecule. UVA (320-400 nm) can damage the DNA only indirectly through a photosensitized reaction. This indirect action is mediated mainly by singlet oxygen, which generates purine base modifications, and has been implicated in the carcinogenic effects of UVA. In order to study the processing of directly and indirectly UV-induced DNA damage in human cells, we first treated the replicating plasmid pRSVcat with up to 10 kJ/m2 UVB or with the photosensitizer methylene blue plus visible light (which generates singlet oxygen) in vitro. Then, the damaged plasmid was transfected into normal or repair deficient xeroderma pigmentosum complementation group A (XP-A) cells. DNA repair was assessed by measuring activity of reactivated chloramphenicol acetyltransferase (CAT) enzyme, encoded by the plasmid's cat gene, in cell extracts after 3 days. While XP-A cells exhibited a significantly reduced repair of UVB-induced DNA damage, they showed a normal repair of singlet oxygen-induced DNA damage. This indicates a differential DNA repair pathway for directly and indirectly UV-induced DNA damage in human cells. Irradiation of the plasmid with UVA alone did not result in a genotoxic effect. Only in conjunction with a cell extract, which provides all candidate cellular photosensitizers, did we find a reduced CAT activity after transfection. This indicates that the genotoxicity of UVA is mediated by a cellular photosensitizer.

Assessment of DNA damage induced by broadband and narrowband UVB in cultured lymphoblasts and keratinocytes using the comet assay.

Phototherapy with broadband UVB is an effective treatment for inflammatory dermatoses. A newly developed fluorescent UVB lamp (Philips TL01) that emits a narrowband UVB around 311 nm was shown to be superior for the phototherapy of psoriasis. In order to contribute to the knowledge about the carcinogenic potential of this UVB source, we measured the DNA damage in lymphoblasts and keratinocytes induced by narrowband UVB and compared it with that by conventional broadband UVB using the single cell gel electrophoresis (comet assay). At equal doses, broadband UVB produced more DNA damage than narrowband UVB. However, in phototherapy of psoriasis, up to 10-fold higher doses are used with TL01. When therapeutically equivalent doses were compared (10-fold correction for narrowband UVB), we found only slight differences in the amount of DNA damage produced by broadband and narrowband UVB. This supports the already existing evidence that for phototherapy narrowband UVB is not more carcinogenic than broadband UVB.

Assessment of genotoxicity and mutagenicity of 1,2-dioxetanes in human cells using a plasmid shuttle vector.

1,2-Dioxetanes are efficient sources of triplet excited carbonyl compounds on thermal decomposition. They cause photochemical and photobiological transformations in the dark. In order to study the genotoxicity and mutagenicity of 1,2-dioxetanes, the replicating shuttle vector pZ189 was damaged with 3,3,4-trimethyl-1,2-dioxetane (TrMD) or 3-hydroxymethyl-3,4,4-trimethyl-1,2-dioxetane (HTMD) in vitro and subsequently transfected into normal human lymphoblasts. We found a dose-dependent increase of genotoxicity (decrease of plasmid survival) and increase of mutation frequency with both dioxetanes. However, TrMD was less mutagenic than HTMD at similar genotoxicity. Sequence analysis of the supF gene revealed more point mutations with TrMD and 100% with HTMD were G:C to T:A and G:C to C:G transversions. These are the typical mutations following 7,8-dihydro-8-oxoguanine (8-oxo-G) formation, the main DNA lesion induced by TrMD and HTMD. Only with TrMD we found 5.4% G:C to A:T transitions, probably reflecting the more pronounced ability of TrMD to form some pyrimidine dimers. Our results indicate that 8-oxo-G is also the most relevant modification in in vivo mutagenesis.

Reduced joining of DNA double strand breaks with an abnormal mutation spectrum in rodent mutants of DNA-PKcs and Ku80.

PURPOSE: To characterize further the contribution of the DNA-PK-dependent dsb repair pathway in mammalian cells. MATERIALS AND METHODS: The efficiency and fidelity of the joining of linear plasmids by DNA-PKcs-defective mouse cells (SCID) and Ku80-defective Chinese hamster ovary cells (xrs-6) was measured using either linear or circular replicating shuttle vector pZ189. RESULTS: The authors found a 3.9-10.7-fold reduced joining of the DNA ends, as compared with wild-type cells. Mutation analysis of the joining site revealed that the joining process was not hypermutable in the mutated cells. However, the SCID and xrs-6 cells produced a different spectrum of mutations at the joining site with a significantly lower proportion of insertions or more complex mutations. CONCLUSIONS: The remaining joining ability of the mutant cells points to an alternative DNA-PK-independent pathway of dsb repair. Comparison of these data with similar data from yeast suggest that the postulated alternative pathway of dsb repair is at least as efficient and less error-prone in rodent cells.

DNA damage formation, DNA repair, and survival after exposure of DNA repair-proficient and nucleotide excision repair-deficient human lymphoblasts to UVA1 and UVB.

PURPOSE: The comet assay has been used to visualize DNA damage in single cells after exposure to UV light. These comets are commonly thought to reflect transient, repair-induced DNA breaks. The goal of the work presented here was to further characterize the nature of UV-induced comets and to further elucidate DNA damage formation by different wavelengths of ultraviolet light. MATERIALS AND METHODS: Detailed dose-response and time-course experiments with comet formation were carried out with normal and nucleotide excision repair (NER)-deficient xeroderma pigmentosum (XP) lymphoblasts. Irradiation was carried out with low, intermediate, or high doses of UVA1 or UVB, comet formation was observed, cell survival and viability were determined, and UV-induced apoptosis was measured. RESULTS: All responses were dose-dependent. With the intermediate dose of UVA1, a pronounced comet formation was observed without subsequent growth inhibition. Raising levels of porphyrins, which act as photosensitizers, by preincubation with 5-amino-levulinic acid increased comet formation with UVA1, but not with UVB. UVA1-sensitivity and comet formation in XP cells was not significantly different from the normal cells. With UVB no comet formation was seen without subsequent apoptotic cell death. XP cells exhibited the known UVB-hypersensitivity, but their comet formation was not significantly different from that of normal cells. CONCLUSIONS: The findings are compatible with the hypothesis that UV-induced comets represent transient repair-induced DNA breaks. Both, the NER of dimers and the base excision repair of oxidative DNA modifications are thought to contribute to comet formation.

Assessment of microsatellite instability in a cell line from a patient with xeroderma pigmentosum variant.

Cells from patients with xeroderma pigmentosum (XP) variant are thought to be defective in postreplication repair. This DNA repair pathway is not well defined in human cells and the exact genetic defect of XP variant is unknown. In another cancer-prone hereditary disorder, hereditary nonpolyposis colon cancer, tumors are characterized by a DNA mismatch repair defect with microsatellite instability. Since there are some similarities between postreplication repair and mismatch repair, we investigated microsatellite instability, the hallmark of a DNA mismatch repair defect, in a lymphoblastoid cell line from a patient with XP variant. Two normal lines and one nucleotide excision repair-defective XP group A line were used as controls. In a host cell microsatellite instability assay, the recently developed shuttle vector pZCA29 was transfected into these cells and replicated plasmid recovered after 3 days. The plasmid contains two CA repeat tracts that interrupt the reading frame of the lacZ gene. Reversion to active beta-galactosidase, detectable by a color reaction of bacterial transformants, represents the frequency of frameshift mutations in the CA repeat tracts during replication of the plasmid, and thereby the host cells' microsatellite instability. We did not find any significant differences in the mutation frequencies of the plasmids after passage through either cell line. This indicates that there is no microsatellite instability in the examined XP variant cell line.

In-vivo assessment of DNA ligation efficiency and fidelity in cells from patients with Fanconi's anemia and other cancer-prone hereditary disorders.

We developed a host cell DNA ligation assay, in which we transfected linearized plasmid pZ189 into human lymphoblasts or fibroblasts in order to assess the efficiency and accuracy of DNA ligation within these host cells. We used cell lines from patients with Fanconi's anemia and other chromosome breakage or instability syndromes (Bloom's syndrome, ataxia telangiectasia, Werner's syndrome). With the Fanconi's anemia lymphoblast line GM8010 we did not find a reduced, but a slightly hypermutable DNA ligation. Mutation analysis revealed a unique 7.9-12.5-fold increase in insertions or complex mutations. With cells from the other chromosome breakage/instability syndromes we also found a hypermutable and/or reduced DNA ligation. An impaired DNA ligation might be a common molecular mechanism of genetic instability in these disorders.

A novel plasmid shuttle vector for the detection and analysis of microsatellite instability in cell lines.

Microsatellite instability is an important feature of tumors from hereditary nonpolyposis colorectal carcinoma (HNPCC) patients as well as a variety of sporadic tumors. Here, we present a novel plasmid shuttle vector for the detection of this replication error (RER+) phenotype in human cell lines. The episomely replicated plasmid pZCA29 harbours the bacterial beta-galactosidase gene interrupted by two palindromically arranged poly-(CA)-repeat tracts. The resulting + 1-frameshift leads to white colonies of Escherichia coli DH10B on X-Gal/IPTG1 agar plates. Mutations in the repeats characteristic of the RER+-phenotype may result in the loss or gain of CA-repeats leading to blue bacterial colonies. We transiently transfected the colorectal cancer cell lines SW480 and HCT116 with the plasmid pZCA29, isolated replicated plasmid DNA after several days and used it to transform E. coli DH10B. We found 1.0 to 1.7% blue colonies after passage of the plasmid through the RER+-cell line SW480 in contrast to 3.5 to 8.1% blue colonies after transfection of the RER+-cell line HCT116, the mutation frequencies increasing with incubation time. Sequence analysis of mutated plasmids revealed mostly 2-bp deletions which occurred especially in one of the repeat tracts. We conclude that pZCA29 appears to be a suitable shuttle vector for the detection and analysis of a RER+-phenotype in cell lines.

Abnormal processing of transfected plasmid DNA in cells from patients with ataxia telangiectasia.

In order to assess spontaneous mutability and accuracy of DNA joining in ataxia telangiectasia, a disorder with spontaneous chromosome breakage, the replicating shuttle vector plasmid, pZ189, was transfected into SV40 virus-transformed fibroblasts from ataxia telangiectasia patients. The ataxia telangiectasia fibroblasts showed elevated frequency of micronuclei, a measure of chromosome breakage. The spontaneous mutation frequency was normal with circular plasmids passed through the ataxia telangiectasia line. These results were compared to those with transformed fibroblasts from a patient with xeroderma pigmentosum, and from a normal donor. Mutation analysis revealed spontaneous point mutations and deletions in the plasmids with all 3 cell lines, however, insertions or complex mutations were only detectable with the ataxia telangiectasia line. To assess DNA-joining ability, linear plasmids which require joining of the DNA ends by host cell enzymes for survival, were transfected into the cells. We found a 2.4-fold less efficient DNA joining in ataxia telangiectasia fibroblasts (p = 0.04) and a 2.0-fold higher mutation frequency (p less than 0.01) in the recircularized plasmids than with the normal line. Plasmid DNA joining and mutation frequency were normal with the xeroderma pigmentosum fibroblasts. These findings with the ataxia telangiectasia fibroblasts of abnormal types of spontaneous mutations in the transfected plasmid and inefficient, error-prone DNA joining may be related to the increased chromosome breakage in these cells. In contrast, an EB virus-transformed ataxia telangiectasia lymphoblast line with normal frequency of micronuclei showed normal types of spontaneous mutations in the transfected plasmid and normal frequency of DNA joining which was error-prone. These data indicate that mechanisms that produce chromosome breakage in ataxia telangiectasia cells can be reflected in processing of plasmid vectors.

Genotoxicity and mutagenicity of the alpha, beta-unsaturated carbonyl compound crotonaldehyde (butenal) on a plasmid shuttle vector.

Crotonaldehyde is an alpha,beta-unsaturated carbonyl compound and an important environmental and industrial toxic substance. Its mutagenic and carcinogenic properties are related to its reactivity to DNA, where it forms different guanine adducts. In order to study the mutagenic consequences of this agent in intact human cells, we treated the shuttle vector plasmid pZ189 with different doses of crotonaldehyde at 37 degrees C for 2 h and then transfected the such damaged plasmid into the normal human lymphoblast cell line GM0621. Within these host cells the guanine adducts are repaired and the plasmids replicated by cellular enzymes. After 2.5 days replicated plasmids were purified from the cells and plasmid survival was quantitated by transformation ability. With increasing doses of crotonaldehyde, we found a significant decline of plasmid survival, reflecting a pronounced genotoxicity of crotonaldehyde-induced DNA damage in intact human cells. Using the plasmid encoded mutagenesis marker gene supF, we were able to screen for mutants and determine mutation frequency in recovered plasmids. A significant increase in mutation frequency with increasing doses of crotonaldehyde reflects mutagenicity of crotonaldehyde-induced DNA damage. Base sequence analysis of recovered mutants revealed 39% point mutations, 46% deletions, and 15% insertions and inversions. Most of the point mutations (82%) were located at G:C base pairs, which is well explained by the DNA damage profile of crotonaldehyde. Among deletions we found a frequent reoccurrence of two hot spot deletions, representing 62% of all deletions. The sites of breakpoints of these deletions hot spots and of other deletions within the plasmid were also found to be sites of DNA breaks, directly induced by crotonaldehyde, as seen in an endlabeled plasmid fragment, treated with crotonaldehyde. Further analysis of the flanking sequences around the deletion breakpoints revealed a high frequency of four different kinds of short sequence homologies of up to eight base pairs.

Relationship of DNA strand breakage produced by bromodeoxyuridine to topoisomerase II activity in Bloom-syndrome fibroblasts.

Cells from patients with Bloom syndrome, a cancer-prone disorder with cutaneous photosensitivity and spontaneous chromosome breakage, exhibit an abnormally increased number of sister-chromatid exchanges following treatment with 5-bromodeoxyuridine (BrdU). This effect has been postulated to be mediated by abnormal topoisomerase II activity. We used alkaline elution to measure DNA single-strand breakage following prolonged exposure to BrdU. Five-day exposure to BrdU produced equal numbers of alkali-labile sites in normal and Bloom-syndrome fibroblasts. These breaks were not protein-associated but were produced by alkali. Treatment with topoisomerase II inhibitors induced similar frequencies of DNA single-strand breaks in normal and Bloom-syndrome fibroblasts. These findings imply that BrdU incorporation into cellular DNA induces alkali-labile DNA lesions that are independent of topoisomerase II activity in Bloom and normal cells.

Role of UVA in the pathogenesis of melanoma and non-melanoma skin cancer. A short review.

It is well established, at least in mice, that not only ultraviolet C (UVC) or ultraviolet B (UVB), but also ultraviolet A (UVA) is able to induce squamous cell carcinomas. Results from animal models, epidemiological studies, and clinical observations suggest that UVA might play an important role in the pathogenesis of malignant melanoma as well. In contrast to UVC or UVB, UVA is hardly able to excite the DNA molecule directly and produces only few pyrimidine dimers. Oxidative DNA base damage, generated indirectly through photosensitizers, might be responsible for the mutagenic and carcinogenic properties of UVA. This is supported by differences in mutation spectra induced by UVA and UVB in mammalian cells and tumors. Avoidance of natural and artificial UVA sources is recommended, especially for melanoma-prone individuals.