The use of plasmid DNA to probe DNA repair functions in the yeast Saccharomyces cerevisiae

The central role of PDR1 in the foundation of yeast drug resistance

The widespread pleiotropic drug resistance (PDR) phenomenon is well described as the long term selection of genetic variants expressing constitutively high levels of membrane transporters involved in drug efflux. However, the transcriptional cascades leading to the PDR phenotype in wild-type cells are largely unknown, and the first steps of this phenomenon are poorly understood. We investigated the transcriptional mechanisms underlying the establishment of an efficient PDR response in budding yeast. We show that within a few minutes of drug sensing yeast elicits an effective PDR response, involving tens of PDR genes. This early PDR response (ePDR) is highly dependent on the Pdr1p transcription factor, which is also one of the major genetic determinants of long term PDR acquisition. The activity of Pdr1p in early drug response is not drug-specific, as two chemically unrelated drugs, benomyl and fluphenazine, elicit identical, Pdr1p-dependent, ePDR patterns. Our data also demonstrate that Pdr1p is an original stress response factor, the DNA binding properties of which do not depend on the presence of drugs. Thus, Pdr1p is a promoter-resident regulator involved in both basal expression and rapid drug-dependent induction of PDR genes.

Fragmentation of Replicating Chromosomes Triggered by Uracil in DNA

The dut mutants of Escherichia coli fail to hydrolyze dUTP and thus incorporate uracil into their DNA, suffering from chromosomal fragmentation. The postulated mechanism for the double-strand DNA breaks is clustered uracil excision, which requires high density of DNA-uracils. However, we did not find enough uracil residues or excision nicks in the DNA of dut mutants to account for clustered uracil excision. Using a dut recBC(Ts) mutant of E.coli to inquire into the mechanism of uracil-triggered chromosomal fragmentation, we show that this fragmentation requires DNA replication and, in turn, inhibits replication of the chromosomal terminus. As a result, origin-containing sub-chromosomal fragments accumulate in dut recBC conditions, indicating preferential demise of replication bubbles. We propose that the basic mechanism of the uracil-triggered chromosomal fragmentation is replication fork collapse at uracil-excision nicks. Possible explanations for the low level terminus fragmentation are also considered.

UV-induced DNA damage in human keratinocytes: Quantitation and correlation with long-term survival

Ultraviolet (UV) radiation has a major role in the pathogenesis of skin cancer due to its capacity to induce immunosuppression and DNA damage in cells. In this study, we describe the use of a novel extra-long polymerase chain reaction (XL-PCR) assay for detection of UV-inducible DNA lesions in a human keratinocyte line (HaCaT cells). Ultraviolet B (UVB), in doses from 4 to 50 mJ/cm2 resulted in a linear increase in the number of DNA lesions in the genome [range 0.3 +/- 0.2 lesions-3.6 +/- 0.7 lesions (mean +/- SD)/10 kb]. At lower doses of UVB (<10 mJ/cm2), 89 +/- 13% lesions were repaired within 24 h of culture. At higher doses, more lesions remained unrepaired, but the repair efficacy expressed as a proportion of repaired lesions to the total amount of DNA lesions remained constant in the range 0-50 mJ/cm2. Moreover, we demonstrated a correlation between the dose of UV and cell survival. The D37 (dose that reduced clonogenic survival to 37%) of UVB equaled 19 mJ/cm2, corresponding to the introduction of 1.4 lesions/10 kb. In contrast to UVB, UVA1 irradiation neither induced measurable DNA damage nor induced cell death in the doses up to 15 J/cm2. In conclusion, the non-radioactive extra-long (XL)-based real-time (RT)-PCR assay system can be used to quantify the UV-induced DNA damage in intact cells. The DNA lesions detected by this assay are mainly induced by short-waved radiation in the UVB range, and unrepaired DNA lesions cause keratinocyte death or permanent cell-cycle block.

Mitotic viability and metabolic competence in UV-irradiated yeast cells

Colony formation is the classic method for measuring survival of yeast cells. This method measures mitotic viability and can underestimate the fraction of cells capable of carrying out other DNA processing events. Here, we report an alternative method, based on cell metabolism, to determine the fraction of surviving cells after ultraviolet (UV) irradiation. The reduction of 2,3,5-triphenyl tetrazolium chloride (or TTC) to formazan in mitochondria was compared with cell colony formation and DNA repair capacity in wt cells and two repair-deficient strains (rad1Delta and rad7Delta). Both TTC reduction and cell colony formation gave a linear response with different ratios of mitotically viable cells and heat-inactivated cells. However, monitoring the formation of formazan in non-dividing yeast cells that are partially (rad7Delta) or totally (wt) proficient at DNA repair is a more accurate measure of cell survival after UV irradiation. Before repair of UV photoproducts (cis-syn cyclobutane pyrimidine dimers or CPDs) is complete, these two assays give very different results, implying that many damaged cells are metabolically competent but cannot replicate. For example, only 25% of the rad7Delta cells are mitotically viable after a UV dose of 12 J/m(2)75% of these cells are metabolically competent and remove over 55% of the CPDs from their genomic DNA. Moreover, repair of CPDs in wt cells dramatically decreases after the first few hours of liquid holding (L.H.; incubation in water) and correlates with a substantial decrease in cell metabolism over the same time period. In contrast, cell colony formation may be the more accurate indicator of cell survival after UV irradiation of rad1Delta cells (i.e., cells with little DNA repair activity). These results indicate that the metabolic competence of UV-irradiated, non-dividing yeast cells is a much better indicator of cell survival than mitotic viability in partially (or totally) repair proficient yeast cultures.

Different repair kinetics for short and long DNA double-strand gaps in Saccharomyces cervisiae

The kinetics of recombinational repair of plasmid DNA double-strand breaks (dsb) and gaps (dsg) of different sizes and ends were studied. For this purpose we used the mutant rad54-3 of the yeast Saccharomyces cerevisiae, which is temperature dependent with respect to genetic recombination and rejoining of dsb/dsg, allowing us to stop these processes by shifting cells to the restrictive temperature. We found that the kinetics of repair of cohesive-ended dsb and small gaps (up to 400 bp) are similar and characterized by two phases separated by a plateau. In contrast, large gap (1.4 kbp) repair proceeds with different kinetics exhibiting only the second phase. We also investigated the repair kinetics of 400 bp gaps introduced into plasmid DNA with and without homology to chromosomal DNA allowing recombinational repair and non-recombinational repair (ligation), respectively. We found that gaps introduced in plasmid sequences homologous to chromosomal DNA are rapidly repaired by recombination. In contrast, recircularization of the gapped plasmid by ligation is as slow and inefficient as ligation of a cohesive-ended dsb. The kinetics of repair of gapped plasmids may be explained by assuming a constitutive level of enzymes responsible for the first phase of recombinational repair, while inducible enzymes, which become available at the end of the plateau, carry out the second phase of repair.

Repair of plasmid and genomic DNA in a rad7 delta mutant of yeast

Repair of UV-induced cyclobutane pyrimidine dimers (CPDs) was examined in a yeast plasmid of known chromatin structure and in genomic DNA in a radiation-sensitive deletion mutant of yeast, rad7 delta, and its isogenic wild-type strain. A whole plasmid repair assay revealed that only approximately 50% of the CPDs in plasmid DNA are repaired after 6 h in this mutant, compared with almost 90% repaired in wild-type. Using a site-specific repair assay on 44 individual CPD sites within the plasmid we found that repair in the rad7 delta mutant occurred primarily in the transcribed regions of each strand of the plasmid, however, the rate of repair at nearly all sites measured was less than in the wild-type. There was no apparent correlation between repair rate and nucleosome position. In addition, approximately 55% of the CPDs in genomic DNA of the mutant are repaired during the 6 h period, compared with > 80% in the wild-type.

Efficient UV stimulation of yeast integrative transformation requires damage on both plasmid strands

The nature of UV-induced pre-recombinational structures was studied using transformation of Saccharomyces cerevisiae cells with non-replicative plasmids. Transformation by double-stranded plasmids irradiated with UV was stimulated up to 50-fold, and both plasmid integration and conversion of the mutated chromosomal selective gene were found to be equally increased. The stimulation observed with such 'totally' irradiated plasmids was not found with plasmids bearing lesions in only one strand. This effect is attributed to the formation by excision repair of recombinogenic structures consisting of a pyrimidine dimer opposite a gap. When single-stranded integrative plasmids were irradiated, their transforming potential was decreased but the proportion of transformants that arose by gene conversion, rather than by plasmid integration, was increased from 8% to 49% as a function of the UV dose. Possible reasons why single-strand UV lesions favour gene conversion are discussed.

Transformation-associated recombination between diverged and homologous DNA repeats is induced by strand breaks

Rearrangements within plasmid DNA are commonly observed during transformation of eukaryotic cells. One possible cause of rearrangements may be recombination between repeated sequences induced by some lesions in the plasmid. We have examined the mechanisms of transformation-associated recombination in the yeast Saccharomyces cerevisiae using a plasmid system which allowed the effects of physical state and/or extent of homology on recombination to be studied. The plasmids contain homologous or diverged (19%) repeats of the URA3 genes (from S. cerevisiae or S. carlsbergensis) separated by the genetically detectable ADE2 colour marker. Recombination during transformation for covalently closed circular plasmids was over 100-fold more frequent than during mitotic growth. The frequency of recombination is partly dependent on the method of transformation in that procedures involving lithium acetate or spheroplasting yield higher frequencies than electroporation. When present in the repeats, unique single-strand breaks that are ligatable, as well as double-strand breaks, lead to high levels of recombination between diverged and identical repeats. The transformation-associated recombination between repeat DNAs is under the influence of the RAD52 and RAD1 genes.

Pleiotropic effects of heterozygosity at the mating-type locus of the yeast Saccharomyces cerevisiae on repair, recombination and transformation

Sexual (MAT a/alpha) and asexual (MAT a/a) strains of the yeast Saccharomyces cerevisiae, which are completely isogenic except at the MAT locus, were compared in their response to ultraviolet radiation. The effects of UV on survival, mitotic intragenic recombination, photoreactivation, and transformation efficiency with UV-irradiated plasmid DNA were examined. The sexual strain had enhanced survival and higher rates of mitotic intragenic recombination compared with the asexual strain. Exposure to visible light subsequent to irradiation increased the survival of both sexual and asexual strains, and decreased their rates of mitotic intragenic recombination. Similar results were obtained by Haladus and Zuk (1980) in their examination of sexual strains homozygous for rad6-1, and wild-type sexuals. Our sexual strain was also consistently more proficient at transforming plasmid DNA, whether that DNA had been irradiated or not. When pre-irradiated with 25 J/m2 of UV, MAT a/alpha cells transformed more efficiently than MAT a/a cells. When subsequently exposed to light, the ability of these pre-irradiated cells to transform decreased for both strains with increasing irradiation of the plasmid. A smaller decrease in transformation efficiency occurred when cells of both strains were kept in the dark. When pre-irradiated with 100 J/m2, the MAT a/alpha cells showed a 2-fold increase in their transformation efficiency of both irradiated and unirradiated plasmids by up to 2-fold, a phenomenon not seen in the MAT a/a cells even when pre-irradiated with much higher doses of UV. This increase in transformation efficiency was not, however, seen in the MAT a/alpha cells when they were exposed to visible light after UV irradiation. These results suggest that cells with the MAT a/alpha genotype have a UV-inducible system that increases the efficiency of transformation in the absence of visible light. This increase in transformation is not an induced increase in the repair of plasmid DNA, but rather an increase in the ability of pre-irradiated MAT a/alpha cells to take up exogenous DNA. MAT a/a cells do not appear to have a similarly inducible system. To the best of our knowledge, this phenomenon has not been previously reported.

Differential repair and recombination of psoralen damaged plasmid DNA in Saccharomyces cerevisiae

Psoralen photoreaction with DNA produces interstrand crosslinks, which require the activity of excision and recombinational pathways for repair. Yeast replicating plasmids, carrying the HIS3, TRP1, and URA3 genes, were photoreacted with psoralen in vitro and transfected into Saccharomyces cerevisiae cells. Repair was assayed as the relative transformation efficiency. A recombination-deficient rad52 strain was the least efficient in the repair of psoralen-damaged plasmids; excision repair-deficient rad1 and rad3 strains had repair efficiencies intermediate between those of rad52 and RAD cells. The level of repair also depended on the conditions of transformant selection; repair was more efficient in medium lacking tryptophan than in medium from which either histidine or uracil was omitted. The plasmid repair differential between these selective media was greatest in rad1 cells, and depended on RAD52. Plasmid-chromosome recombination was stimulated by psoralen damage, and required RAD52 function. Chromosome to plasmid gene conversion was seen most frequently at the HIS3 locus. In RAD and rad3 cells, the majority of the conversions were associated with plasmid integration, while in rad1 cells most were non-crossover events. Plasmid to chromosome gene conversion was observed most frequently at the TRP1 locus, and was accompanied by plasmid loss.

Repair of ultraviolet light damage in Saccharomyces cerevisiae as studied with double- and single-stranded incoming DNAs

Purified double- and single-stranded DNAs of the autonomously replicating vector M13RK9-T were irradiated with ultraviolet light (UV) in vitro and introduced into competent whole cells of Saccharomyces cerevisiae. Incoming double-stranded DNA was more sensitive to UV in excision repair-deficient rad2-1 cells than in proficient repair RAD+ cells, while single-stranded DNA exhibited high sensitivity in both host cells. The results indicate that in yeast there is no effective rescue of UV-incoming single-stranded DNA by excision repair or other constitutive dark repair processes.

Repair of exogenous (plasmid) DNA damaged by photoaddition of 8-methoxypsoralen in the yeast Saccharomyces cerevisiae

The contribution of different repair pathways to the repair of 8-methoxypsoralen (8-MOP) plus UVA induced lesions on a centromeric plasmid (YCp50) was investigated in the yeast Saccharomyces cerevisiae using the lithium acetate transformation method. The pathways of excision-resynthesis (RAD1) and recombination (RAD52) were found to be involved in the repair of exogenous as well as of genomic DNA. Mutants in RAD6 and PSO2 genes showed the same transformation efficiency with 8-MOP plus UVA treated plasmid as wild-type cells suggesting that these latter pathways involved in mutagenesis are not operating on plasmid DNA although required for the repair of 8-MOP photoadducts induced in genomic DNA. These results indicate that DNA-repair gene products may be differently involved in the repair of exogenous and endogenous DNA depending on the repair system and the nature of the DNA damage considered.

Transformation of Saccharomyces cerevisiae with UV-irradiated single-stranded plasmid

UV-irradiated single-stranded replicative plasmids were used to transform different yeast strains. The low doses of UV used in this study (10-75 J/m2) caused a significant decrease in the transforming efficiency of plasmid DNA in the Rad+ strain, while they had no effect on transformation with double-stranded plasmids of comparable size. Neither the rev3 mutation, nor the rad18 or rad52 mutations influenced the efficiency of transformation with irradiated single-stranded plasmid. However, it was found to be decreased in the double rev3 rad52 mutant. Extracellular irradiation of plasmid that contains both URA3 and LEU2 genes (psLU) gave rise to up to 5% Leu- transformants among selected Ura+ ones in the repair-proficient strain. Induction of Leu- transformants was dose-dependent and only partially depressed in the rev3 mutant. These results suggest that both mutagenic and recombinational repair processes operate on UV-damaged single-stranded DNA in yeast.

Genetic control of plasmid DNA double-strand gap repair in yeast, Saccharomyces cerevisiae

The repair of double-strand gaps (DSGs) in the plasmid DNA of radiosensitive mutants of Saccharomyces cerevisiae has been analyzed. The proportion of repair events that resulted in complete plasmid DNA DSG recovery was close to 100% in Rad+ cells. Mutation rad55 does not influence the efficiency and preciseness of DSG repair. The mutant rad57, which is capable of recombinational DNA DSB repair, resulted in no DSG recovery. Mutation rad53 substantially inhibits the efficiency of DSG repair but does not influence the precision of repair. Plasmid DNA DSG repair is completely blocked by mutations rad50 and rad54.

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.

Repair of UV-damaged incoming plasmid DNA in Saccharomyces cerevisiae

A whole-cell transformation assay was used for the repair of UV-damaged plasmid DNA in highly transformable haploid strains of Saccharomyces cerevisiae having different repair capabilities. Six rad alleles were selected from the three epistasis groups: rad 1-1 and rad2-1 from the RAD3 group, rad6-1 and rad18-2 from the RAD6 group, and rad52-1 and rad54-1 from the RAD52 group. Cells carrying single, double and triple rad alleles were transformed to uracil prototrophy by centromeric plasmid DNA (YCp19) modified in vitro with UV (254 nm). Surviving fractions were calculated as the number of transformants at each fluence relative to the number of transformants with unirradiated plasmid DNA. The sensitivity of incoming DNA in single rad mutants shows that most repair is carried out by excision repair and a RAD18-dependent process. In the rad52-1 host, the sensitivity of incoming DNA was intermediate between those found in RAD+ and rad2-1 hosts, suggesting the involvement of a recombinational repair process. Non-epistatic interactions were observed between rad alleles belonging to different epistasis groups. This provides validation for the classification of the three epistasis groups concerning the repair of chromosomal DNA for UV-incoming DNA. In both rad1-1 rad6-1 and rad1-1 rad18-2 rad54-1 hosts, the mean fluence for one lethal event corresponds approximately to one pyrimidine dimer per plasmid molecule, indicating that they are absolute repairless hosts for incoming DNA. A comparison between cell and plasmid survival reveals that there are differences in the repairability of both chromosomal and incoming DNA. The large effect of rad6-1 mutation on cell survival and the small effect on incoming DNA suggest that, in the RAD+ strain, the RAD6 product may be essential for the repair processes which act on chromosomal DNA, but not for those which act on incoming DNA. It is proposed that in yeasts postreplication repair of incoming DNA is limited to supercoiled molecules with 1-2 pyrimidine dimers that can initiate replication.

Use of damaged plasmid to study DNA repair in X-ray sensitive (xrs) strains of Chinese hamster ovary (CHO) cells

The effect of gamma-irradiation of pSV2gpt DNA on its transfection frequency has been analysed using CHO xrs mutants. Xrs mutants are sensitive to ionizing radiation and show a defect in double-strand break (dsb) rejoining. At low doses a sharp decrease in relative transfection frequency, i.e. transfection frequency of irradiated plasmid relative to untreated plasmid, was observed in the xrs mutants compared with the parent line K1. Electrophoresis of the irradiated plasmid DNA showed that the decrease in transfection frequency in the xrs mutants correlated with the change of supercoiled molecules into open-circular forms. One explanation for these results is that the xrs gene could play a part in the integration or repair of open-circular molecules produced by gamma-radiation. In the parent line CHO-K1, open-circular and supercoiled molecules have the same transfection frequency. The effect of linearization of pSV2gpt DNA by restriction enzymes on transfection frequency in xrs and wild-type strains has also been examined. In contrast to the above results we have not detected a difference in the relative transfection frequency between xrs and wild-type strains. The results suggest that restricted plasmid DNA is subject to extensive nucleolytic degradation, and this occurs to equal extents in wild type and mutant strains.

Induction of homologous recombination in Saccharomyces cerevisiae

We have investigated the effects of UV irradiation of Saccharomyces cerevisiae in order to distinguish whether UV-induced recombination results from the induction of enzymes required for homologous recombination, or the production of substrate sites for recombination containing regions of DNA damage. We utilized split-dose experiments to investigate the induction of proteins required for survival, gene conversion, and mutation in a diploid strain of S. cerevisiae. We demonstrate that inducing doses of UV irradiation followed by a 6 h period of incubation render the cells resistant to challenge doses of UV irradiation. The effects of inducing and challenge doses of UV irradiation upon interchromosomal gene conversion and mutation are strictly additive. Using the yeast URA3 gene cloned in non-replicating single- and double-stranded plasmid vectors that integrate into chromosomal genes upon transformation, we show that UV irradiation of haploid yeast cells and homologous plasmid DNA sequences each stimulate homologous recombination approximately two-fold, and that these effects are additive. Non-specific DNA damage has little effect on the stimulation of homologous recombination, as shown by studies in which UV-irradiated heterologous DNA was included in transformation/recombination experiments. We further demonstrate that the effect of competing single- and double-stranded heterologous DNA sequences differs in UV-irradiated and unirradiated cells, suggesting an induction of recombinational machinery in UV-irradiated S. cerevisiae cells.

The molecular genetics of the incision step in the DNA excision repair process

This review describes the evolution of research into the genetic basis of how different organisms use the process of excision repair to recognize and remove lesions from their cellular DNA. One particular aspect of excision repair, DNA incision, and how it is controlled at the genetic level in bacteriophage, bacteria, S. cerevisae, D. melanogaster, rodent cells and humans is examined. In phage T4, DNA is incised by a DNA glycosylase-AP endonuclease that is coded for by the denV gene. In E. coli, the products of three genes, uvrA, uvrB and uvrC, are required to form the UVRABC excinuclease that cleaves DNA and releases a fragment 12-13 nucleotides long containing the site of damage. In S. cerevisiae, genes complementing five mutants of the RAD3 epistasis group, rad1, rad2, rad3, rad4 and rad10 have been cloned and analyzed. Rodent cells sensitive to a variety of mutagenic agents and deficient in excision repair are being used in molecular studies to identify and clone human repair genes (e.g. ERCC1) capable of complementing mammalian repair defects. Most studies of the human system, however, have been done with cells isolated from patients suffering from the repair defective, cancer-prone disorder, xeroderma pigmentosum, and these cells are now beginning to be characterized at the molecular level. Studies such as these that provide a greater understanding of the genetic basis of DNA repair should also offer new insights into other cellular processes, including genetic recombination, differentiation, mutagenesis, carcinogenesis and aging.

Repair of double-strand breaks in plasmid DNA in the yeast Saccharomyces cerevisiae

We studied the repair of double-strand breaks (DSB) in plasmid DNA introduced into haploid cells of the yeast Saccharomyces cerevisiae. The efficiency of repair was estimated from the frequency of transformation of the cells by an autonomously replicated linearized plasmid. The frequency of "lithium" transformation of Rad+ cells was increased greatly (by 1 order of magnitude and more) compared with that for circular DNA if the plasmid was initially linearized at the XhoI site within the LYS2 gene. This effect is due to recombinational repair of the plasmid DNA. Mutations rad52, rad53, rad54 and rad57 suppress the repair of DSB in plasmid DNA. The kinetics of DSB repair in plasmid DNA are biphasic: the first phase is completed within 1 h and the second within 14-18 h of incubating cells on selective medium.

Inactivation by nitrogen mustard of plasmids introduced into normal and Fanconi's anaemia cells

An SV40-transformed Fanconi's anaemia (FA) cell line, GM6914, exhibits approximately 2.4-fold increased sensitivity to the cytotoxic effects of nitrogen mustard (NM) when compared with the normal line, MRC5-V1. Host cell reactivation of NM-treated plasmid has been investigated using transient expression vectors which contain the chloramphenicol acetyltransferase (CAT) gene. In both cell types there is a similar, dose-dependent reduction in CAT expression which correlates with an increase in NM-induced DNA-interstrand crosslinking. The data are consistent with two possible mechanisms for inactivation of the plasmid. Either a single crosslink anywhere within the plasmid is sufficient to prevent transcription of the cat gene. Alternatively, inactivation may result from some other more prevalent NM-induced lesions within the cat coding sequence.

Inactivation of DNA-mediated transformation of hamster cells by gamma-rays and deoxyribonuclease I

DNA damage has been induced in the mammalian expression vector pSV2-gpt by irradiation with X-rays or treatment with deoxyribonuclease I (DNAase I) under controlled conditions in vitro. The biological effect of such treatment was assessed by stable gene expression in Chinese hamster ovary (CHO) cells using DNA-mediated gene transfer. Induction of DNA double-strand breaks (dsbs), resulting from the interaction of independently-induced single-strand breaks (ssbs) under the present conditions, was measured by agarose gel electrophoresis of the treated vector. The correlation between radiation-induced gene inactivation and dsb induction mediated by OH radicals suggests that a dsb in the gene is a major inactivating lesion in this system. Individual radiation-induced ssbs and nucleotide damage are produced much more frequently than dsbs under these conditions, but the majority of these lesions do not appear to inactivate the gpt gene. DNAase I treatment, giving only simple 5' P + 3' OH breaks in the vector DNA, gave a correlation of approximately 1.5 dsb in the gpt gene per inactivating event, confirming little repair of dsbs in this system. Inactivation of the gpt gene without appreciable formation of dsbs was found, however, when the vector was irradiated at high dose rate in the presence of the OH-radical scavenger KBr. The nature of non-break damage causing inactivation requires further study.

Single-strand breaks can lead to complex configurations of plasmid DNA in vitro

DNA species which migrate extremely slowly in agarose gel electrophoresis may be formed from plasmid DNA containing radiation-induced single-strand breaks (ssbs). Postirradiation heat treatment in low ionic strength buffer and subsequent incubation with Mg2+ strongly enhanced the formation of these species. Electron micrographs taken after such treatment show numerous complex configurations containing DNA material from several plasmid molecules. Less extreme formation of slowly migrating DNA occurred without postirradiation heat treatment or Mg2+ incubation when the DNA was co-precipitated with calcium phosphate in a physiologically balanced buffer and incubated under conditions used for DNA-mediated gene transfer. The data suggest that homologous pairing between single-stranded regions formed in relation to ssbs may contribute to cohesion between different molecules. The significance of the cohesion process for gene transfer experiments and cellular radiation effects is discussed.

Repair of UV-irradiated plasmid DNA in Saccharomyces cerevisiae. Inability to complement mutational defects in excision repair by in vitro treatment with Micrococcus luteus UV endonuclease

Excision repair defects of Saccharomyces cerevisiae rad1-1, rad4-4, rad7-1 and rad14 mutants were examined. As previously found, transformation of such cells with UV-irradiated plasmid DNA is poor compared to wild-type yeast. Treatment of UV-irradiated YRp12 plasmid DNA with crude preparations of Micrococcus luteus UV endonuclease before introducing it into rad1-1 cells increased transformation efficiency to wild-type levels. This is consistent with earlier reports of rad1-1 mutants being defective in the incision step of excision repair. However, with purified UV endonuclease little or no rescue occurred when the UV-irradiated plasmid was incised before transformation into rad1-1 or rad4-4 cells. Furthermore, the purified UV endonuclease reduced transformation of rad7-1 and rad14 mutants to levels seen in rad1-1 and rad4-4 cells. In contrast such treatment caused only a small decrease in the transforming ability of UV-irradiated DNA in wild-type cells. These results show that yeast can normally process pre-incised, UV-irradiated DNA and that this activity is absent in rad1-1, rad4-4, rad7-1 and rad14 mutants. Thus, in addition to their previously reported roles in incision, the RAD1, 4, 7 and 14 gene products are also required for repair to continue after the incision of DNA lesions.

Induced cellular resistance to ultraviolet light in Saccharomyces cerevisiae is not accompanied by increased repair of plasmid DNA

Many reports show that resistance of Saccharomyces cerevisiae to a large UV dose can be enhanced by pre-induction with a smaller one given some hours before. This work tests if such increased cell survival is associated with increased DNA repair on UV damaged plasmid transformed into yeast. There was no change in transformation efficiency of UV-damaged plasmid DNA under conditions where RAD cell survival increased 5-fold, and where rad1-1 and rad6-1 survival increased 2-fold. It is concluded that DNA repair activity involving the RAD6 and RAD3 pathways is either not inducible or is unable to work on plasmid DNA. It is suggested that the enhancement of cellular survival detected may be based on changes in cell-cycle behaviour which permit cells generally proficient in repair a greater chance to recover.