DNA repair in a small yeast plasmid folded into chromatin.

The question of whether excision repair of yeast plasmids accurately reflects the repair of yeast genomic chromatin has yielded conflicting answers. These conflicts could have arisen from differences in the conformation of plasmid molecules used during these studies. We have examined excision repair of UV photoproducts in a small (2619 bp) autonomously replicating plasmid (YRp-TRURAP), known to be folded into chromatin with positioned nucleosomes in vivo, in the yeast Saccharomyces cerevisiae. A quantitative assay was used to measure the yield of cyclobutane pyrimidine dimers (PD) in plasmid DNA by measuring the fraction of Form I molecules resistant to T4 endonuclease V. After a UV dose of 100 J/m2, which yields 1.2 PD/plasmid in irradiated cells, radiation insensitive (wt) cells repair approximately 70% of the PD in TRURAP chromatin in 2 hr (a rate comparable to that of genomic chromatin). On the other hand, no measurable repair occurs in TRURAP chromatin in radiation sensitive cells (rad1) during the same time period. Thus, this small plasmid contains sufficient chromatin structure in vivo to reflect the incompetent repair of genomic chromatin seen in a rad mutant, while maintaining the competent repair level in wt cells.     

Efficient repair of 8-oxo-7,8-dihydrodeoxyguanosine in human and hamster xeroderma pigmentosum D cells

The repair of the endogenous lesion 8-oxo-7,8-dihydrodeoxyguanosine (8-oxodG) was investigated in the nucleotide excision repair mutant xeroderma pigmentosum D (XPD), using human normal or transformed XPD fibroblasts and the Chinese hamster XPD cell line UV5. In vivo repair of 8-oxodG induced by hydrogen peroxide treatment and analyzed by high-performance liquid chromatography/electrochemical detection was normal in the XPD mutant fibroblasts XP15PV and GM434, as compared to normal human fibroblasts GM970, GM5757, and GM6114. Similar results were obtained with the human SV40-transformed XPD mutant cell line GM8207 in comparison to the control cell line GM637. Repair of 8-oxodG was even slightly (2-3-fold) but reproducibly increased in Chinese hamster XPD mutant UV5 cells, as compared to parental AA8 cells. This unexpected effect was reversed by transfection in UV5 cells of a wild-type XPD cDNA and confirmed in in vitro experiments in which a plasmid substrate containing a single 8-oxoG was repaired by UV5 cell extracts. The data show that repair of 8-oxodG is normal in XPD cells, thus indicating that the neurological complications of XPD patients may not be linked to in vivo accumulation of this lesion.     

Ultraviolet mutational spectrum in a shuttle vector propagated in xeroderma pigmentosum lymphoblastoid cells and fibroblasts

In order to examine possible cell-type specificity in mutagenic events, a shuttle-vector plasmid, pZ189, carrying a bacterial suppressor tRNA marker gene, was treated with ultraviolet radiation and propagated in Epstein-Barr virus transformed lymphoblastoid cell lines from a patient, XP12BE, with xeroderma pigmentosum (XP), group A, and a normal control. XP is a skin-cancer-prone disorder with UV hypersensitivity and defective DNA repair. Plasmid survival and mutations inactivating the marker gene were scored by transforming an indicator strain of E. coli. An earlier report on this data [Seetharam et al., (1990) J. Mol. Biol., 212, 433] indicated lower survival and higher mutation frequency with the UV-treated plasmid passed through the XP12Be(EBV) line. In the present report, sequence analysis of 198 mutant plasmids revealed a predominance of G:C----A:T transitions with both lymphoblastoid cell lines. This finding is consistent with the bias of polymerases toward insertion of an adenine opposite non-coding photoproducts (dinucleotides or other lesions). Transversion mutagenesis, non-adjacent double mutations, and triple-base mutations may involve other mechanisms. These results were compared to similar data from a fibroblast line from the same patient [Bredberg et al., (1986) Proc. Natl. Acad. Sci. (U.S.A.), 83, 8273]. The frequency of G:C----A:T transitions was higher, and there were fewer plasmids with multiple-base substitutions and with transversion mutations with both XP lymphoblasts and fibroblasts than with the normal lymphoblasts and fibroblasts. There were no significant differences in classes or types of mutations in the UV-treated plasmid replicated in the XP lymphoblasts and the XP fibroblasts. This suggests that the major features of UV mutagenesis in different cell types from the same individual are similar.     

DNA excision in repair proficient and deficient human cells treated with a combination of ultraviolet radiation and acridine mustard (ICR-170) or 4-nitroquinoline 1-oxide

Excision repair was measured in normal human and xeroderma pigmentosum group C fibroblasts treated with ultraviolet radiation and the carcinogens acridine mustard (ICR-170) or 4-nitroquinoline 1-oxide (4NQO) by the techniques of unscheduled synthesis, photolysis of bromodeoxyuridine incorporated into parental DNA during repair, and assays of sites sensitive to ultraviolet (UV)-endonuclease. Doses of ICR-170 and 4NQO, low enough not to inhibit unscheduled DNA synthesis (UDS), caused damage to DNA that was repaired by a long patch type mechanism and the rates of UDS decreased rapidly in the first 12 h after treatment. Repair after a combined action of UV plus ICR-170 or UV plus 4NQO was additive in normal cells and no inhibition of loss of endonuclease sensitive sites was detected. In xeroderma pigmentosum (XP) C cells there was less repair after UV plus ICR-170 than after each treatment separately; whereas there was an additive effect after UV plus 4NQO and no inhibition of loss of endonuclease sensitive sites. The results indicate that in normal human fibroblasts there are different rate limiting steps for removal of chemical and physical damages from DNA and that XP cells have a different repair system for ICR-170, not just a lower level, than normal cells. Possibly the same long patch repair system works on 4NQO damage in both normal and XP cells.     

A sensitive flow cytometry-based nucleotide excision repair assay unexpectedly reveals that mitogen-activated protein kinase signaling does not regulate the removal of UV-induced DNA damage in human cells

In response to diverse genotoxic stimuli (e.g. UV and cisplatin), the mitogen-activated protein kinases ERK1/2, JNK1/2, and p38alpha/beta become rapidly phosphorylated and in turn activate multiple downstream effectors that modulate apoptosis and/or growth arrest. Furthermore, previous lines of evidence have strongly suggested that ERK1/2 and JNK1/2 participate in global-genomic nucleotide excision repair, a critical antineoplastic pathway that removes helix-distorting DNA adducts induced by a variety of mutagenic agents, including UV. To rigorously evaluate the potential role of mitogen-activated protein kinases in global-genomic nucleotide excision repair, various human cell strains (primary skin fibroblasts, primary lung fibroblasts, and HCT116 colon carcinoma cells) were treated with highly specific chemical inhibitors, which, following UV exposure, (i) abrogated the capacities of ERK1/2, JNK1/2, or p38alpha/beta to phosphorylate specific downstream effectors and (ii) characteristically modulated cellular proliferation, clonogenic survival, and/or apoptosis. A highly sensitive flow cytometry-based nucleotide excision repair assay recently optimized and validated in our laboratory was then employed to directly demonstrate that the kinetics of UV DNA photoadduct repair are highly similar in mock-treated versus mitogen-activated protein kinase inhibitor-treated cells. These data on primary and tumor cells treated with pharmacological inhibitors were fully corroborated by repair studies using (i) short hairpin RNA-mediated knockdown of ERK1/2 or JNK1/2 in human U2OS osteosarcoma cells and (ii) expression of a dominant negative p38alpha mutant in human primary lung fibroblasts. Our results provide solid evidence for the first time, in disaccord with a burgeoning perception, that mitogen-activated protein kinase signaling does not influence the efficiency of human global-genomic nucleotide excision repair.     

Characterization of biotinylated repair regions in reversibly permeabilized human fibroblasts.

We have examined the incorporation of biotinyl-11-deoxyuridine triphosphate (BiodUTP) into excision repair patches of UV-irradiated confluent human fibroblasts. Cells were reversibly permeabilized to BiodUTP with lysolecithin, and biotin was detected in DNA on nylon filters using a streptavidin/alkaline phosphatase colorimetric assay. Following a UV dose of 12 J/m2, maximum incorporation of BioUTP occurred at a lysolecithin concentration (80-100 micrograms/mL) similar to that for incorporation of dTTP. Incorporation of BiodUTP into repair patches increased with UV dose up to 4 and 8 J/m2 in two normal human fibroblast strains, while no incorporation of BiodUTP was observed in xeroderma pigmentosum (group A) human fibroblasts. The repair-incorporated biotin was not removed from the DNA over a 48-h period, and only slowly disappeared after longer times (approximately 30% in 72 h), while little of the biotin remained in cells induced to divide. Furthermore, the stability of the biotin in repaired DNA was unaffected by a second dose of UV radiation several hours after the biotin-labeling period to induce a "second round" of excision repair. Exonuclease III digestion and gap-filling with DNA polymerase I indicate that the majority of biotin-labeled repair patches (approximately 80%) are rapidly ligated in confluent human cells. However, the remaining patches were not ligated after a 24-h chase period, in contrast to dTTP-labeled repair patches. The BiodUMP repair label in both chromatin and DNA is preferentially digested by staphylococcal nuclease, preventing the use of this enzyme for nucleosome mapping in these regions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Enhancement of repair of UV-irradiated plasmids in cultured fish cells by fluorescent light preillumination and growth arrest.

The UV-irradiated plasmid pBSCATSV, which could express chloramphenicol acetyltransferase (CAT) in the presence of SV40 early promoter, was transfected into RBCF-1 cells derived from the goldfish (Carassius auratus). The cells were incubated in the dark for 24 h and then the CAT activity was measured. CAT expression relative to non-irradiated control was calculated. The CAT expression of the exponentially growing cells transfected with UV-irradiated plasmid was enhanced by fluorescent light (FL) preillumination of the cells 8 h before transfection. The efficiency of photorepair (PR) measured by CAT expression was also enhanced by the same FL preillumination. This suggests that FL preillumination enhances both photorepair and dark repair of RBCF-1 cells for UV-damaged plasmid transfected into the cells. The enhancement of repair of UV damage by FL preillumination was also observed in survival assays. When the UV-irradiated pBSCATSV was transfected into growth-arrested cells in confluent culture, CAT expression was less sensitive to UV irradiation, and FL preillumination was much less effective in enhancing photorepair and dark repair.     

Human cells (normal and ataxia telangiectasia) transfected with pR plasmid are hypersensitive to DNA strand-breaking agents.

Ataxia telangiectasia (AT) cells are known to be hypersensitive to ionizing radiations and to drugs such as bleomycin and epipodophyllotoxin VP16, a topoisomerase II poison. Both of these produce DNA double-strand breaks even if through different mechanisms. In this work we analyzed the sensitivity to bleomycin and to epipodophyllotoxin of AT cells after transfection with pR plasmid. This plasmid, interacting with bacterial SOS repair pathways, expresses itself in mammalian cells conferring cell resistance to the SOS inducers UV and 4NQO and cell sensitivity to different drugs such as bleomycin. This effect is presumably due to the interaction of pR products with double-strand breaks. Our findings indicate that pR plasmid, in both AT lines tested (AT5BIVA fibroblasts and ATL6 lymphoblasts), expresses itself (increasing UV protection) and amplifies the already enhanced AT cell sensitivity to both bleomycin and VP16.     

Repair of UV-irradiated plasmid DNA in mutants of Saccharomyces cerevisiae and Escherichia coli deficient in repair of pyrimidine dimers

The repair of in vitro UV-irradiated DNA of plasmid pBB29 was studied in excision defective yeast mutants rad1, rad2, rad3, rad4, rad10 and in Escherichia coli mutants uvr- and recA-, by measuring the cell transformation frequency. Rad2, rad3, rad4, and rad10 mutants could repair plasmid DNA despite their inability to repair nuclear DNA, whereas the reduced ability of rad1 mutant for plasmid DNA repair demonstrated alone the same dependence on the host functions that are needed for nuclear DNA repair. In E. coli the repair of UV-irradiated plasmid DNA is carried out only by the excision-repair system dependent on uvr genes. Treatment of UV-irradiated plasmid DNA with UV endonuclease from Micrococcus luteus greatly enhances the efficiency of transformation of E. coli uvr- mutants. Similar treatment with cell-free extracts of yeast rad1 mutant or wild-type strains as well as with nuclease BaL31, despite their ability for preferential cutting of UV damaged DNA, showed no influence on cell transformation.     

Cell cycle regulation of DNA repair in normal and repair deficient human cells

The regulation of nucleotide excision repair and base excision repair by normal and repair deficient human cells was determined. Synchronous cultures of WI-38 normal diploid fibroblasts and Xeroderma pigmentosum fibroblasts (complementation group D) (XP-D) were used to investigate whether DNA repair pathways were modulated during the cell cycle. Two criteria were used: (1) unscheduled DNA synthesis (UDS) in the presence of hydroxyurea (HU) after exposure to UV light or after exposure to N-acetoxy-acetylaminofluorene (N-AcO-AAF) to quantitate nucleotide excision repair or UDS after exposure to methylmethane sulfonate (MMS) to measure base excision repair; (2) repair replication into parental DNA in the absence of HU after exposure to UV light. Nucleotide excision repair after UV irradiation was induced in WI-38 fibroblasts during the cell cycle reaching a maximum in cultures exposed 14–15 h after cell stimulation. Similar results were observed after exposure to N-AcO-AAF. DNA repair was increased 2–4-fold after UV exposure and was increased 3-fold after N-AcO-AAF exposure. In either instance nucleotide excision repair was sequentially stimulated prior to the enhancement of base excision repair which was stimulated prior to the induction of DNA replication. In contrast XP-D failed to induce nucleotide excision repair after UV irradiation at any interval in the cell cycle. However, base excision repair and DNA replication were stimulated comparable to that enhancement observed in WI-38 cells. The distinctive induction of nucleotide excision repair and base excision repair prior to the onset of DNA replication suggests that separate DNA repair complexes may be formed during the eucaryotic cell cycle.     

Postreplication repair of DNA in human fibroblasts after UV irradiation or treatment with metabolites of benzo(a)pyrene

We have examined the ability of normal fibroblasts and of excision-deficient xeroderma pigmentosum (XP) and XP variant fibroblasts to perform postreplication DNA repair after increasing doses of either ultraviolet (UV) irradiation or mutagenic benzo(a)pyrene derivatives. XP cells defective in the excision of both UV-induced pyrimidine dimers and guanine adducts induced by treatment with the 7,8-diol-9,10-epoxides of benzo(a)pyrene were partially defective in their ability to synthesize high molecular weight DNA after the induction of both classes of DNA lesions. This defect was more marked in XP variant cells, despite their ability to remove by excision repair both pyrimidine dimers and the diol epoxide-induced lesions to the same degree as observed in normal cells. The benzo(a)pyrene 9,10-oxide had no effect in any of the 3 cell lines. The response of the excision and postreplication DNA repair mechanisms operating in human fibroblasts treated with benzo(a)pyrene 7,8-diol-9,10-epoxides, therefore, appears to resemble closely that seen after the induction of pyrimidine dimers by UV irradiation.     

Clinical and biochemical studies in three patients with severe early infantile Cockayne syndrome

Summary We present clinical and biochemical data from three patients with severe Cockayne syndrome (CS) of very early onset. Unlike in classic CS, signs became evident in the first weeks of life and led to unusually early death. Fibroblasts from two of the patients showed a complete defect of the repair of UV-induced thymine dimer lesions. They were unable to remove thymine dimer lesions from their DNA, had a severe reduction of the RNA synthesis rates after UV irradiation, and showed no reactivation of an UV-inactivated indicator gene and no DNA recondensation after UV irradiation. DNA repair investigated in these two fibroblast cell strains resembled that of xeroderma pigmentosum cells of complementation group A. In contrast, fibroblasts from the third patient showed the same in vitro repair characteristics as classic CS cells.     

Inhibition of transient gene expression in Chinese hamster ovary cells by cyclobutane dimers and (6-4) photoproducts in transfected ultraviolet-irradiated plasmid DNA

Using a transient gene expression assay to measure host cell reactivation, the effects of cyclobutane dimer and noncyclobutane dimer uv photoproducts on expression of a reporter gene were examined in normal and repair-deficient Chinese hamster ovary (CHO) cell lines. Ultraviolet damage in plasmid pRSV beta gal DNA, containing the Escherichia coli beta-galactosidase gene, resulted in reduced reporter gene expression in both uv-hypersensitive mutant CHO cell lines UV5 and UV61 relative to wild-type, parental AA8 cells. However, the effects of uv irradiation of transfected plasmid DNA on gene activity were reduced in UV61, a mutant with normal (6-4) photoproduct repair, compared to UV5, which is deficient in (6-4) photoproduct repair; this reduction correlated with the intermediate uv-hypersensitivity of UV61. Selective removal of cyclobutane dimers by in vitro photoreactivation of uv-irradiated plasmid DNA prior to transfection substantially increased reporter gene activity in both uv-hypersensitive mutant cell lines. This increase was significantly greater in UV61 than in UV5, consistent with UV5 being deficient in repair of both (6-4) photoproducts and cyclobutane dimers. These results suggest that unrepaired (6-4) photoproducts in transfected pRSV beta gal plasmid DNA are responsible for a significant fraction of the reduction in transient gene expression observed in recipient uv-hypersensitive CHO cell mutants.     

Effect of nucleotide excision repair in human cells on intrachromosomal homologous recombination induced by UV and 1-nitrosopyrene.

To study the role of nucleotide excision repair in the induction of intrachromosomal homologous recombination in mammalian cells, we introduced a plasmid containing a substrate for recombination into three human cell lines that differ in their repair capacity and compared the frequency of recombination induced by UV radiation and by 1-nitrosopyrene. One strain had a normal capacity for nucleotide excision repair, the second exhibited an intermediate rate of repair, and the third, derived from a patient with xeroderma pigmentosum, had no ability to repair UV- or 1-nitrosopyrene-induced DNA damage. The endogenous thymidine kinase genes in these cell strains had been inactivated, and the cells contained an integrated copy of a plasmid carrying duplicated copies of the herpes simplex virus type 1 thymidine kinase (Htk) gene, each inactivated by an 8-base-pair XhoI site inserted at a unique site. A functional tk gene can only be generated by a productive recombination event between the two Htk genes. In all three stains, UV and 1-nitrosopyrene induced dose-dependent increases in the frequency of recombinants. However, the doses required to cause a specific increase in recombination in the repair-deficient strains were 10 to 30 times lower than the dose required for the cell strain with a normal capacity for repair. These results strongly suggest that unexcised DNA lesions, rather than excision repair per se, stimulate intrachromosomal homologous recombination. Southern blot analysis of DNA from representative recombinants indicated that in all cases one of the two Htk genes had become wild type (XhoI resistant). The majority (90%) retained the Htk duplication, consistent with nonreciprocal transfer of genetic information (gene conversion).     

Effect of host lex, recA, recF, and uvrD genotypes on the ultraviolet light-protecting and related properties of plasmid R46 in Escherichia coli.

The ability of plasmid R46 to reduce the lethal but enhance the mutagenic effect of ultraviolet (UV) irradiation was tested in sets of Escherichia coli K-12 derivatives, wild type or with different mutations affecting DNA repair capacity, but otherwise isogenic. UV protection and enhancement of UV mutagenic effect were obtained in uvrA6, uvrB5, uvrD3, and recF143 hosts, but not in a recA56 strain. The plasmid gave some UV protection in two lexA1 and two lexA101 strains and in one lexA102 host, but produced no such effect in another lexA102 host. The plasmid restored UV mutagenic effect in a lexB30 strain, the yield of induced mutants per survivor of irradiation (10 J/m2) being about the same for the lexB30(R46) and lex+(R46) strains; by contrast the plasmid, though it reduced the UV sensitivity of the lexB30 strain, did not make it as UV-resistant as the lex+ R-strain.     

DNA Repair in Human/Embryonic Chick Heterokaryons: Ability of Each Species to Aid the Other in the Removal of Ultraviolet-Induced Damage

Cultured human and embryonic chick fibroblasts possess different enzyme-mediated processes to repair cyclobutyl pyrimidine dimers induced in their deoxyribonucleic acid (DNA) by ultraviolet (UV) radiation. While dimers are corrected in human cells by excision repair, a photoenzymatic repair process exists in embryonic chick cells for the removal of these potentially deleterious UV photoproducts. We have utilized a sensitive enzymatic assay to monitor the disappearance, i.e. repair, of dimer-containing sites in fused populations of human and chick cells primarily consisting of multinucleate human/chick heterokaryons. Fused cultures were constructed such that UV photoproducts were present only in chick DNA when evaluating excision repair and only in human DNA when evaluating photoenzymatic repair. Based on the kinetics of site removal observed in these cultures we are led to conclude the following: Within heterokaryons per se the photoreactivating enzyme derived from chick nuclei and at least one excision-repair enzyme (presumably a UV endonuclease) derived from human nuclei act on UV-damaged DNA in foreign nuclei with an efficiency equal to that displayed toward their own nuclear DNA. Hence, after cell fusion these chick and human repair enzymes are apparently able to diffuse into foreign nuclei and once therein competently attack UV-irradiated DNA independently of its origin. In harmony with the situation in nonfused parental cultures, in heterokaryons the chick photoenzymatic repair process rapidly removed all dimer-containing sites from human DNA including the residual fraction normally acted upon slowly by the human excision-repair process.     

A re-examination of the intragenome distribution of repaired sites in proliferating xeroderma pigmentosum complementation group C fibroblasts.

We find that rapidly proliferating fibroblasts from xeroderma pigmentosum complementation group C (XP-C) patients, cells that have a small residual DNA excision repair capacity, repair DNA in localized regions of the genome in a clustered pattern rather than at single sites in dispersed locations. This finding is similar to that observed earlier for nondividing cells but is in contrast to published results that indicate that the residual repair in proliferating XP-C cells is dispersed throughout the genome in a non-clustered pattern. While we detect the same amount of repair in both proliferating and nondividing cells, we also observe no shift from the clustered pattern of repair to a more dispersive pattern when nondividing cells are stimulated to proliferate by fresh serum addition. We have no obvious explanation for these discrepancies with the published results. We have noted previously that proliferating XP-C cells are very UV sensitive relative to normal cells while nondividing cells that exhibit the same amount of repair activity are relatively UV resistant. There is no satisfactory explanation for this change in relative response to the lethal effects of UV, a change not observed for cell strains from other XP complementation groups. However, we argue that clustered repair in specific genomic regions promotes survival in nondividing XP-C cells but does not promote survival in proliferating cells.