A p53-independent pathway for induction of p21waf1cip1 and concomitant G1 arrest in UV-irradiated human skin fibroblasts.

Largely on the basis of studies using the potent clastogen ionizing radiation, it has been widely assumed that up-regulation of the cyclin-dependent kinase inhibitor p21(waf1cip1) in cultured cells exposed to DNA-damaging agents is contingent upon the presence of functional p53 tumor suppressor protein. Nevertheless, we demonstrate here that the model mutagen 254-nm UV light induces p21(waf1cip1) protein and concomitant G1 arrest in normal human skin fibroblasts, as well as in p53-deficient fibroblasts derived from cancer-prone Li-Fraumeni syndrome patients. However, as expected, following exposure to ionizing radiation, elevated p21(waf1cip1) protein levels and G1 arrest were observed only in normal fibroblasts. These data provide a prominent and clinically relevant example in which p21(waf1cip1)-mediated growth arrest occurs independently of p53 in human cells treated with a model DNA-damaging agent.

The multilayered organization of engineered human skin does not influence the formation of sunlight-induced cyclobutane pyrimidine dimers in cellular DNA.

Solar UVB initiates skin cancer mainly by generating highly premutagenic cyclobutane pyrimidine dimers (CPDs) and subsequent mutations in critical growth control genes. It is universally presumed that the upper epidermis in human skin blocks a significant portion of the incident UVB, thereby protecting the cancer-prone basal layer from CPD formation. Using two sensitive techniques for measuring CPD in cellular DNA, we confirmed that the multilayered organization of engineered human skin efficiently shields the basal layer against 254-nm UVC (which is not present in terrestrial sunlight) but, very unexpectedly, provides virtually no protection against environmentally relevant UVB. This underscores the importance of regular sunscreen use, which, in light of our data, may constitute a considerably more important first line of defense against photocarcinogenesis than previously believed.

Ablation of p21waf1cip1 expression enhances the capacity of p53-deficient human tumor cells to repair UVB-induced DNA damage.

During periods of genotoxic stress, the cyclin-dependent kinase inhibitor p21waf1cip1 (hereafter referred to as p21) is transcriptionally up-regulated by the p53 tumor suppressor and subsequently plays a key role in cellular growth arrest. Investigations have also indicated that p21 may regulate nucleotide excision repair, a critical pathway that removes carcinogenic DNA damage induced by UV light and other mutagens. In this study, we examined whether low levels of endogenous p21 expression can modulate nucleotide excision repair in p53-deficient human tumor cells after UVB exposure. For this purpose, we used the well-characterized p53-/-p21+/+ adenocarcinoma cell strain DLD1 and its isogenic counterpart carrying a homozygous knockout for p21 (p53-/-p21-/- DLD1). Because p53-/-p21+/+ DLD1 expresses very low levels of endogenous p21 protein that are not up-regulated after mutagen exposure, this strain has been considered functionally p21-deficient in the cellular response to DNA damage. Nonetheless, the ligation-mediated PCR technology was used here to demonstrate, at nucleotide resolution, that p53-/-p21+/+ DLD1 excises UVB-induced cyclobutane pyrimidine dimers from the c-jun proto-oncogene at a significantly lower rate than the isogenic p53-/-p21-/- derivative. The higher efficiency of DNA repair in UVB-exposed p53-/-p21-/- DLD1 cells is accompanied by increased clonogenic survival and reduced levels of apoptosis, relative to the p53-/-p21+/+ counterpart. Our results show that ablation of p21 expression can significantly enhance the capacity of p53-deficient human tumor cells to repair UVB-induced DNA damage.

Southern analysis of genomic alterations in gamma-ray-induced aprt- hamster cell mutants.

The role of genomic alterations in mutagenesis induced by ionizing radiation has been the subject of considerable speculation. By Southern blotting analysis we show here that 9 of 55 (approximately 1/6) gamma-ray-induced mutants at the adenine phosphoribosyl transferase (aprt) locus of Chinese hamster ovary (CHO) cells have a detectable genomic rearrangement. These fall into two classes: intragenic deletions and chromosomal rearrangements. In contrast, no major genomic alterations were detected among 67 spontaneous mutants, although two restriction site loss events were observed. Three gamma-ray-induced mutants were found to be intragenic deletions; all may have identical break-points. The remaining six gamma-ray-induced mutants demonstrating a genomic alteration appear to be the result of chromosomal rearrangements, possibly translocation or inversion events. None of the remaining gamma-ray-induced mutants showed any observable alteration in blotting pattern indicating a substantial role for point mutation in gamma-ray-induced mutagenesis at the aprt locus.

Investigation of the mutagenic specificity of X-rays using a retroviral shuttle vector in CHO cells.

In some biological systems ionizing radiation appears to induce large deletions and rearrangements, while in others point mutations predominate the mutational spectrum. Moreover, while the point mutations are often randomly distributed, some systems exhibit "hot spots." Retroviral shuttle vectors are particularly useful for investigating the basis of these differences since the genetic target can be conveniently analyzed in a variety of host backgrounds and genomic locations. We have studied the mutational specificity of X-rays in a Chinese hamster ovary cell line (CHO) containing a stably integrated retroviral shuttle vector, carrying the CHO aprt cDNA as the genetic target. Cells were irradiated with 7 Gy using a 180 kVp X-ray source. The predominant mutation (87% of all APRT mutants), as determined by Southern analysis, was the complete deletion of the shuttle vector construct. In addition, 23 APRT mutants, carrying an apparently intact shuttle vector, were characterized at the sequence level: 5 were transitions, 9 were transversions, 3 were small deletions or insertions, 4 were frameshifts, and 2 were small rearrangements. Although the type and the location of the point mutations characterized appeared largely random, small deletions, insertions, and frameshifts were frequently associated with direct sequence repeats.

UV-induced G:C-->A:T transitions at the APRT locus of Chinese hamster ovary cells cluster at frequently damaged 5'-TCC-3' sequences.

We have determined the relative frequency in vitro of UV-induced cyclobutane pyrimidine dimers (py <> py) and (6-4) pyrimidine pyrimidone photoproducts (py(6-4)pyo) at individual sites in selected regions of the Chinese hamster ovary (CHO) adenine phosphoribosyltransferase (aprt) gene, and compared this to the observed specificity of UV-induced mutations (Drobetsky et al., 1987, 1989). Our results indicate that G:C-->A:T transition "hotspots" (multiple occurrences) at the chromosomal CHO aprt locus, the majority of which occur at 5'TCC-3', are clearly targeted at sites associated with a relatively high yield of py <> py and/or py(6-4)pyo. We conclude that photoproduct frequency plays a major role in UV-induced transition mutagenesis at 5'-TCC-3' sites at an endogenous locus in a rodent cell line, and that both py(6-4)pyo and py <> py have premutagenic potential.

The nature of ultraviolet light-induced mutations at the heterozygous aprt locus in Chinese hamster ovary cells.

A system for studying mutational specificity at a heterozygous locus in Chinese hamster ovary (CHO) cells is described. The strategy employed is based on restriction fragment analysis and DNA sequencing of enzymatically amplified mutant adenine phosphoribosyltransferase (aprt) alleles. We have demonstrated the usefulness of this approach through the characterization of a collection of aprt- mutants with respect to the role played by loss of heterozygosity events in ultraviolet light (UV) induced mutagenesis. A similar strategy has also been applied to speculate on the identity of the premutational lesion responsible for a UV-induced mutational hotspot at the aprt locus.

Perspectives on the use of an endogenous gene target in studies of mutational specificity.

Mutational spectra have become increasingly important tools in generating a molecular level understanding of mutagenesis in mammalian cells. The work in this field has primarily involved the use of shuttle vector systems although some work has also been reported using endogenous cellular genes as mutational targets. In this communication we discuss the relative utility of these two approaches. We specifically focus on UV light-induced mutagenesis since this agent has been studied in both types of system. We conclude that shuttle vector and endogenous gene studies of mutagenesis are highly complementary, each possessing unique advantages.

Mutational specificity studies of endogenous mammalian cell loci: methodological aspects.

We report here the details of a modified cloning method first described by Seed et al. (1983) for use in an extensive study of mutational specificity at the aprt locus of Chinese hamster ovary cells. The technology depends on homologous recombination between a suppressor probe plasmid and the desired insert in a genomic library constructed in a double amber mutant bacteriophage lambda vector. Recombinant phage form blue plaques on a non-suppressor, lacZ amber host. We have determined the sensitivity of the method. Homologous recombination frequency is in the order of 10(-3), 6-7 orders of magnitude above non-homologous events. Recombination efficiency is unaffected when the target phage is diluted 100,000-fold with parental vector. A background of plaques is observed along with the desired blue plaques. Although the color discrimination permits us to easily avoid these background plaques, we have characterized the frequency and the nature of these events.

A role for ultraviolet A in solar mutagenesis.

It is well established that exposure to solar UVB (290-320 nm) gives rise to mutations in oncogenes and tumor suppressor genes that initiate the molecular cascade toward skin cancer. Although UVA (320-400 nm) has also been implicated in multistage photocarcinogenesis, its potential contribution to sunlight mutagenesis remains poorly characterized. We have determined the DNA sequence specificity of mutations induced by UVB (lambda > 290 nm), and by UVA (lambda > 350 nm), at the adenine phosphoribosyltransferase locus of Chinese hamster ovary cells. This has been compared to results previously obtained for stimulated sunlight (lambda > or = 310 nm) and 254-nm UVC in the same gene. We demonstrate that T-->G transversions, a generally rare class of mutation, are induced at high frequency (up to 50%) in UVA-exposed cells. Furthermore, this event comprises a substantial proportion of the simulated sunlight-induced mutant collection (25%) but is significantly less frequent (P < 0.05) in cells irradiated with either UVB (9%) or UVC (5%). We conclude that the mutagenic specificity of broad-spectrum solar light in rodent cells is not determined entirely by the UVB component and that UVA also plays an important role.

8-Methoxypsoralen induced mutations are highly targeted at crosslinkable sites of photoaddition on the non-transcribed strand of a mammalian chromosomal gene.

We have determined the mutational specificity of 8-methoxypsoralen photoaddition at the endogenous adenine phosphoribosyltransferase gene of Chinese hamster ovary cells hemizygous for this locus. In addition, the distribution of 8-methoxypsoralen photo-adducts was resolved in vitro at the DNA sequence level, and compared with the observed site specificity for mutation. Among 27 mutants characterized, all were single base changes at AT base pairs: 16 A:T-->T:A, six A:T-->C:G, four A:T-->G:C and one -T frameshift. All these vents were targeted to potential sites of photoaddition. The vast majority of these sites were also detectable in vitro, suggesting that 8-methoxypsoralen plus UVA-induced mutational hotspots may be damage hotspots. Furthermore 26/27 mutations occurred at crosslinkable 5'TpA sites, supporting the notion that 8-methoxypsoralen biadducts rather than monoadducts are major premutagenic lesions in mammalian cells. Since 90% of our mutation collection could have resulted from damage on the non-transcribed strand, it appears that photoadducted thymine residues on the transcribed strand of the adenine phosphoribosyltransferase gene may be preferentially repaired. We therefore suggest a model for mutagenesis, induced by psoralen biadducts, based on the preferential incision of biadducts followed by translesion synthesis past modified T bases persisting on the non-transcribed strand.

The specificity of UV-induced mutations at an endogenous locus in mammalian cells.

We have used a rapid in vivo recombinational method to clone and completely sequence 34 UV-induced mutants at the adenine phosphoribosyltransferase (APRT) locus of Chinese hamster ovary cells. Among the mutants recovered, 26 were single base substitutions including 17 G.C----A.T transitions and a single A.T----G.C transition. Three of the 4 possible transversions accounted for the remaining 8 mutations. The G.C----T.A transversion was not recovered. Six tandem double or closely neighboring double-base substitutions, one double mutation consisting of a G.C----T.A transversion and an adjacent frameshift, as well as one single frameshift mutation were also recovered. UV-induced mutation appears to be targeted to dipyrimidine sites with only two exceptions. These include two double mutations where only one of the base substitutions occurred at a dipyrimidine site. The observed specificity of UV-light-induced mutations at the APRT locus is consistent with the argument that G.C----A.T transitions result primarily from the (6-4) pyrimidine pyrimidone lesion. A striking resemblance in the distribution of UV-induced mutants and a collection of 30 spontaneous mutants identified recently in our laboratory was noted. Both share a common strong site of multiple occurrence and a considerable degree of overlap with respect to site specificity. We speculate therefore that DNA context plays a significant role in mutation fixation in mammalian cells.

Mutagenic specificity of solar UV light in nucleotide excision repair-deficient rodent cells.

To investigate the role of nucleotide excision repair (NER) in the cellular processing of carcinogenic DNA photoproducts induced by defined, environmentally relevant portions of the solar wavelength spectrum, we have determined the mutagenic specificity of simulated sunlight (310-1100 nm), UVA (350-400 nm), and UVB (290-320 nm), as well as of the "nonsolar" model mutagen 254-nm UVC, at the adenine phosphoribosyltransferase (aprt) locus in NER-deficient (ERCC1) Chinese hamster ovary (CHO) cells. The frequency distributions of mutational classes induced by UVB and by simulated sunlight in repair-deficient CHO cells were virtually identical, each showing a marked increase in tandem CC-->TT transitions relative to NER-proficient cells. A striking increase in CC-->TT events was also previously documented for mutated p53 tumor-suppressor genes from nonmelanoma tumors of NER-deficient, skin cancer-prone xeroderma pigmentosum patients, compared to normal individuals. The data therefore indicate that the aprt gene in NER-deficient cultured rodent cells irradiated with artificial solar light generates the same distinctive "fingerprint" for sunlight mutagenesis as the p53 locus in NER-deficient humans exposed to natural sunlight in vivo. Moreover, in strong contrast to the situation for repair-component CHO cells, where a significant role for UVA was previously noted, the mutagenic specificity of simulated sunlight in NER-deficient CHO cells and of natural sunlight in humans afflicted with xeroderma pigmentosum can be entirely accounted for by the UVB portion of the solar wavelength spectrum.

The mutational specificity of simulated sunlight at the aprt locus in rodent cells.

To elucidate the nature of sunlight mutagenesis in mammalian cells, the mutational specificity of simulated solar light (SSL) has been established at the Chinese hamster ovary adenine phosphoribosyltransferase (aprt) locus. Among a collection of 36 independent SSL-induced mutations, the majority were single or tandem double C-->T transitions at dipyrimidine sites. This is consistent with previous investigations of 254 nm UVC on the aprt gene, as well as on various other genetic targets from diverse species, and supports a pre-eminent role for cyclobutane dimers and/or (6-4) photoproducts in solar mutagenesis. However, some substantial differences were also noted in the frequency and distribution of mutational classes generated by SSL versus UVC at the aprt locus. In particular, a reduction in the proportion of SSL-induced C-->T transitions was accompanied by significant increases in the incidence of T-->G transversions (25% versus 6%, P < 0.05) and of tandem double CC-->TT events at mutational hotspots (25% versus 9%, P < 0.05). Furthermore, a much greater fraction of SSL-induced mutations could be attributed to photoproducts on the non-transcribed strand of the aprt gene than was observed following treatment with 254 nm UV (94% versus 64%, P < 0.002). The general significance of these disparities between SSL and UVC mutagenesis at the aprt locus remains to be established, underscoring the need for further investigations on the effects of solar light in mammalian cells.

A yeast homologue of the human phosphotyrosyl phosphatase activator PTPA is implicated in protection against oxidative DNA damage induced by the model carcinogen 4-nitroquinoline 1-oxide.

The model carcinogen 4-nitroquinoline 1-oxide (4-NQO) has historically been characterized as "UV-mimetic" with respect to its genotoxic properties. However, recent evidence indicates that 4-NQO, unlike 254-nm UV light, may exert significant cytotoxic and/or mutagenic potential via the generation of reactive oxygen species. To elucidate the response of eukaryotic cells to 4-NQO-induced oxidative stress, we isolated Saccharomyces cerevisiae mutants exhibiting hypersensitivity to the cytotoxic effects of this mutagen. One such mutant, EBY1, was cross-sensitive to the oxidative agents UVA and diamide while retaining parental sensitivities to 254-nm UV light, methyl methanesulfonate, and ionizing radiation. A complementing gene (designated yPTPA1), restoring full UVA and 4-NQO resistance to EBY1 and encoding a protein that shares 40% identity with the human phosphotyrosyl phosphatase activator hPTPA, has been isolated. Targeted deletion of yPTPA1 in wild type yeast engendered the identical pattern of mutagen hypersensitivity as that manifested by EBY1, in addition to a spontaneous mutator phenotype that was markedly enhanced upon exposure to either UVA or 4-NQO but not to 254-nm UV or methyl methanesulfonate. Moreover, the yptpa1 deletion mutant exhibited a marked deficiency in the recovery of high molecular weight DNA following 4-NQO exposure, revealing a defect at the level of DNA repair. These data (i) strongly support a role for active oxygen intermediates in determining the genotoxic outcome of 4-NQO exposure and (ii) suggest a novel mechanism in yeast involving yPtpa1p-mediated activation of a phosphatase that participates in the repair of oxidative DNA damage, implying that hPTPA may exert a similar function in humans.

Human cells compromised for p53 function exhibit defective global and transcription-coupled nucleotide excision repair, whereas cells compromised for pRb function are defective only in global repair.

After exposure to DNA-damaging agents, the p53 tumor suppressor protects against neoplastic transformation by inducing growth arrest and apoptosis. A series of investigations has also demonstrated that, in UV-exposed cells, p53 regulates the removal of DNA photoproducts from the genome overall (global nucleotide excision repair), but does not participate in an overlapping pathway that removes damage specifically from the transcribed strand of active genes (transcription-coupled nucleotide excision repair). Here, the highly sensitive ligation-mediated PCR was employed to quantify, at nucleotide resolution, the repair of UVB-induced cyclobutane pyrimidine dimers (CPDs) in genetically p53-deficient Li-Fraumeni skin fibroblasts, as well as in human lung fibroblasts expressing the human papillomavirus (HPV) E6 oncoprotein that functionally inactivates p53. Lung fibroblasts expressing the HPV E7 gene product, which similarly inactivates the retinoblastoma tumor-suppressor protein (pRb), were also investigated. pRb acts downstream of p53 to mediate G(1) arrest, but has no demonstrated role in DNA repair. Relative to normal cells, HPV E6-expressing lung fibroblasts and Li-Fraumeni skin fibroblasts each manifested defective CPD repair along both the transcribed and nontranscribed strands of the p53 and/or c-jun loci. HPV E7-expressing lung fibroblasts also exhibited reduced CPD removal, but only along the nontranscribed strand. Our results provide striking evidence that transcription-coupled repair, in addition to global repair, are p53-dependent in UV-exposed human fibroblasts. Moreover, the observed DNA-repair defect in HPV E7-expressing cells reveals a function for this oncoprotein in HPV-mediated carcinogenesis, and may suggest a role for pRb in global nucleotide excision repair.

Perspectives on UV light mutagenesis: investigation of the CHO aprt gene carried on a retroviral shuttle vector.

The extent to which the cellular processing of shuttle vector-carried genes reflects that of endogenous chromosomal loci has been a subject of considerable controversy. In order to address this issue, we have developed a retroviral-based shuttle vector carrying the Chinese hamster ovary (CHO) adenine phosphoribosyltransferase (aprt) gene stably integrated into the genome to be used for studying mutational specificity in mammalian cells. Initially, we have characterized a collection of UV-induced mutants in a CHO cell background. We have therefore been able to directly compare this shuttle vector data to that previously obtained for UV-induced mutation at the endogenous CHO (aprt) locus. Although some potential differences between the two spectra have been noted, there appears to be a remarkable similarity in the distribution and site specificity of UV-induced mutations. These similarities extend to extrachromosomal shuttle vectors as well and consolidate the role of shuttle vectors as powerful analytical tools for studying mechanisms of point mutagenesis in mammalian cells.

Base substitutions, frameshifts, and small deletions constitute ionizing radiation-induced point mutations in mammalian cells.

The relative role of point mutations and large genomic rearrangements in ionizing radiation-induced mutagenesis has been an issue of long-standing interest. Recent studies using Southern blotting analysis permit the partitioning of ionizing radiation-induced mutagenesis in mammalian cells into detectable deletions and major genomic rearrangements and into point mutations. The molecular nature of these point mutations has been left unresolved; they may include base substitutions as well as small deletions, insertions, and frame-shifts below the level of resolution of Southern blotting analysis. In this investigation, we have characterized a collection of ionizing radiation-induced point mutations at the endogenous adenine phosphoribosyltransferase (aprt) locus of Chinese hamster ovary cells at the DNA sequence level. Base substitutions represented approximately equal to 2/3 of the point mutations analyzed. Although the collection of mutants is relatively small, every possible type of base substitution event has been recovered. These mutations are well distributed throughout the coding sequence with only one multiple occurrence. Small deletions represented the remainder of characterized mutants; no insertions have been observed. Sequence-directed mechanisms mediated by direct repeats could account for some of the observed deletions, while others appear to be directly attributable to radiation-induced strand breakage.

The COI mitochondrial gene encodes a minor histocompatibility antigen presented by H2-M3.

We found that (LP x C57BL/6)F1 mice could raise a CTL response against parental C57BL/6 cells. These CTLs recognized a maternally transmitted, H2-M3wt-restricted, minor histocompatibility Ag (MiHA) that is widely distributed among many strains of mice and encoded by the COI mitochondrial gene. The wild-type MiHA is the COI N-terminal hexapeptide. Sequencing the 5' end of the COI gene in LP and C57BL/6 mice showed that the LP allele arose by a T-->C transition in the third codon, which caused substitution of threonine for isoleucine. Molecular characterization of this MiHA and the demonstration that it is presented exclusively by H2-M3: 1) support the concept that differential expression of MiHA in MHC-identical animals is caused by polymorphism of the MiHA gene proper; 2) expand our knowledge of the repertoire of self-peptides naturally presented by H2-M3 and show that this MHC class I molecule can present short endogenous peptide ligands; and 3) suggest that mitochondrial DNA mutations that modify the repertoire of H2-M3-associated mitochondrial peptides are representative of mitochondrial DNA mutations in general.