Excision of damaged thymine residues from gamma-irradiated poly(dA-dT) by crude extracts of Escherichia coli

Sources of extracellular, oxidatively-modified DNA lesions: implications for their measurement in urine

There is a robust mechanistic basis for the role of oxidation damage to DNA in the aetiology of various major diseases (cardiovascular, neurodegenerative, cancer). Robust, validated biomarkers are needed to measure oxidative damage in the context of molecular epidemiology, to clarify risks associated with oxidative stress, to improve our understanding of its role in health and disease and to test intervention strategies to ameliorate it. Of the urinary biomarkers for DNA oxidation, 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG) is the most studied. However, there are a number of factors which hamper our complete understanding of what meausrement of this lesion in urine actually represents. DNA repair is thought to be a major contributor to urinary 8-oxodG levels, although the precise pathway(s) has not been proven, plus possible contribution from cell turnover and diet are possible confounders. Most recently, evidence has arisen which suggests that nucleotide salvage of 8-oxodG and 8-oxoGua can contribute substantially to 8-oxoG levels in DNA and RNA, at least in rapidly dividing cells. This new observation may add an further confounder to the conclusion that 8-oxoGua or 8-oxodG, and its nucleobase equivalent 8-oxoguanine, concentrations in urine are simply a consequence of DNA repair. Further studies are required to define the relative contributions of metabolism, disease and diet to oxidised nucleic acids and their metabolites in urine in order to develop urinalyis as a better tool for understanding human disease.

Does measurement of oxidative damage to DNA have clinical significance?

Oxidative damage to DNA is the seemingly inevitable consequence of cellular metabolism. Furthermore, despite protective mechanisms, cellular levels of damage may increase under conditions of oxidative stress, arising from exposure to a variety of physical or chemical insults. Elevated levels of oxidatively damaged DNA have been measured in numerous diseases, and as a result, it has been hypothesised that such damage plays an integral role in the aetiology of that disease. This review examines the validity of this hypothesis, exploring the mechanisms by which oxidative DNA damage may lead to disease. We conclude that further validation of biomarkers of oxidative DNA damage, along with further elucidation of the role of damage in disease, may allow these biomarkers to become potentially useful clinical tools.

Progress in the analysis of urinary oxidative DNA damage

Oxidative DNA damage has been implicated to be important in the pathogenesis of many diseases, including cancer and heart disease. The assessment of damage in various biological matrices, such as DNA, serum, and urine, is vital to understanding this role and subsequently devising intervention strategies. Despite the numerous techniques to measure oxidative DNA damage products in urine, it remains unclear what these measurements truly represent. Sources of urinary lesions may include the diet, cell death, and, of most interest, DNA repair. Were it possible to exclude the two former contributions, a noninvasive assay for DNA repair would be invaluable in the study of DNA damage and disease. This review highlights that, although progress has been made, significant work remains. Diet, cell death, and repair need continued examination to further elucidate the kinetics of lesion formation and clearance in vivo. Studies from our laboratory and others are making appreciable progress towards the interpretation of urinary lesion measurements along with the development of urinary assays to evaluate DNA repair. Upon establishment of these details, urinary oxidative DNA damage measurements may become more than a reflection of generalized oxidative stress.

Urinary 8-oxo-2'-deoxyguanosine--source, significance and supplements

Oxidative damage to cellular biomolecules, in particular DNA, has been proposed to play an important role in a number of pathological conditions, including carcinogenesis. A much studied consequence of oxygen-centred radical damage to DNA is 8-oxo-2'-deoxyguanosine (8-oxodG). Using numerous techniques, this lesion has been quantified in various biological matrices, most notably DNA and urine. Until recently, it was understood that urinary 8-oxodG derives solely from DNA repair, although the processes which may yield the modified deoxynucleoside have never been thoroughly discussed. This review suggests that nucleotide excision repair and the action of a specific endonuclease may, in addition to the nucleotide pool, contribute significantly to levels of 8-oxodG in the urine. On this basis, urinary 8-oxodG represents an important biomarker of generalised, cellular oxidative stress. Current data from antioxidant supplementation trials are examined and the potential for such compounds to modulate DNA repair is considered. It is stressed that further work is required to link DNA, serum and urinary levels of 8-oxodG such that the kinetics of formation and clearance may be elucidated, facilitating greater understanding of the role played by oxidative stress in disease.

Monoclonal antibodies to thymidine glycol generated by different immunization techniques

Monoclonal antibodies specific for thymidine glycol in oxidized DNA were generated by immunization with thymidine glycol monophosphate (TMP-OH) or thymidine glycol (T-OH), respectively, conjugated to keyhole limpet hemocyanin (KLH) or thyreoglobulin (TG). Forty-five clones (TMP-OH) and 70 clones (T-OH) were examined upon antibody production in ELISA. Four clones secreting IgG1, kappa, were characterized further. In several studies the antibodies derived from the immunization with TMP-OH were inhibited by various inhibitors. In descending order of effectiveness, they were thymidine glycol monophosphate (TMP-OH), thymidine glycol (T-OH), thymidine monophosphate (TMP), and thymidine (Thn). After immunization with T-OH, antibodies were inhibited in following order: T-OH > TMP-OH > TMP > Thn. Inhibition by the bases thymine, adenine, cytosine, and guanine were negligible. In ISB (Immuno Slot Blot) performed with OsO4-treated DNA (Poly-[dA-dT]) and amount of 70 fmol thymidine glycol was detectable. DNA had to be irradiated at a level of at least 20 Gy to detect any damage in ELISA but at a lower level of irradiation (10 Gy) in ISB by one of these antibodies, TPS-1. The antibodies obtained after immunization with hapten-protein are therefore capable of the detection of low frequency lesions in DNA generated by free radicals after radiation or oxidative stress.

Production of oxidative DNA damage during the metabolic activation of benzo[a]pyrene in human mammary epithelial cells correlates with cell killing

We have studied the generation of reactive oxygen species during the metabolism of a carcinogen, benzo[a]pyrene, by human mammary epithelial cells. We have quantitated the production of one type of oxidative DNA damage, thymine glycols, by using a monoclonal antibody specific to this base modification. Thymine glycols were produced in DNA in a dose-dependent manner after exposure of human mammary epithelial cells to benzo[a]pyrene. The number of thymine glycols formed in the DNA was similar to that of 7,8-dihydroxy-9,10-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene covalently bound to the DNA. Exposure of cells to the carcinogen in the presence of superoxide dismutase, which reduces superoxide anions, inhibited the production of thymine glycols and increased cell survival but had little effect on adduct formation. At equitoxic doses, approximately equal to 10-fold more thymine glycols were formed after exposure to benzo[a]pyrene than to gamma-irradiation. Thymine glycols, produced by either agent, were efficiently removed from the DNA of the cells. Since thymine glycols represent only a portion of the oxidative damage possibly produced, our results indicate that the total amount of oxidative damage induced during the exposure of human mammary epithelial cells to benzo[a]pyrene greatly exceeds the amount produced by direct adduct formation and that this indirect damage plays an important role in the cytotoxicity of benzo[a]pyrene.

Inflammation, oxidative DNA damage, and carcinogenesis

Inflammation has long been associated with carcinogenesis, especially in the promotion phase. The mechanism of action of the potent inflammatory agent and skin promoter 12-tetradecanoyl phorbol-13-acetate (TPA) is unknown. It is thought that TPA selectively enhances the growth of initiated cells, and during this process, initiated cells progress to the preneoplastic state and eventually to the malignant phenotype. Many studies support the multistep nature of carcinogenesis, and a significant amount of evidence indicates that more than one genetic event is necessary for neoplastic transformation. Selective growth stimulation of initiated cells by TPA does not explain how further genetic events may occur by chronic exposure to this nongenotoxic agent. We and others have proposed that TPA may work, in part, by inciting inflammation and stimulating inflammatory cells to release powerful oxidants which then induce DNA damage in epidermal cells. Macrophages cocultured with target cells and TPA induce oxidized thymine bases in the target cells. This process is inhibited by both catalase and inhibitors of lipoxygenases, suggesting the involvement of both H2O2 and oxidized lipid products. Furthermore, macrophage populations that release both H2O2 and metabolites of arachidonic acid (AA) are more efficient at inducing oxidative DNA damage in surrounding cells than populations which only release H2O2 or metabolites of AA. In vivo studies demonstrated that SENCAR mice, which are sensitive to promotion by TPA, have a more intense inflammatory reaction in skin than C57LB/6 mice, which are resistant to promotion by TPA. In addition, macrophages from SENCAR mice release more H2O2 and metabolites of AA, and induce more oxidative DNA damage in cocultured cells than macrophages from C57LB/6 mice.(ABSTRACT TRUNCATED AT 250 WORDS)

Production of thymine glycols in DNA by radiation and chemical carcinogens as detected by a monoclonal antibody

In order to understand the role in carcinogenesis of damage indirectly induced by chemical carcinogens, it is important to identify the primary DNA lesions. We have measured the formation and repair of one type of DNA modification, 5,6-dihydroxydihydrothymine (thymine glycol), following exposure of cultured human cells to the carcinogens N-hydroxy-2-naphthylamine or benzo(a)pyrene. The efficiency of production of thymine glycols in DNA by these carcinogens was compared to that by ionizing radiation and ultraviolet light. Thymine glycols were detected using a monoclonal antibody against this product in a sensitive immunoassay. We found that thymine glycols were produced in DNA in a dose dependent manner after exposure to the carcinogens and that their production was reduced if either catalase or superoxide dismutase or both were present at the time of treatment. The efficiency of thymine glycol production following exposure to the chemical carcinogens was greater than that following equi-toxic doses of radiation. Thymine glycols were efficiently removed from the DNA of human cells following treatment with either the chemical carcinogens, ionizing radiation or ultraviolet light.

Formation of cytosine glycol and 5,6-dihydroxycytosine in deoxyribonucleic acid on treatment with osmium tetroxide

OsO4 selectively forms thymine glycol lesions in DNA. In the past, OsO4-treated DNA has been used as a substrate in studies of DNA repair utilizing base-excision repair enzymes such as DNA glycosylases. There is, however, no information available on the chemical identity of other OsO4-induced base lesions in DNA. A complete knowledge of such DNA lesions may be of importance for repair studies. Using a methodology developed recently for characterization of oxidative base damage in DNA, we provide evidence for the formation of cytosine glycol and 5,6-dihydroxycytosine moieties, in addition to thymine glycol, in DNA on treatment with OsO4. For this purpose, samples of OsO4-treated DNA were hydrolysed with formic acid, then trimethylsilylated and analysed by capillary gas chromatography-mass spectrometry. In addition to thymine glycol, 5-hydroxyuracil (isobarbituric acid), 5-hydroxycytosine and 5,6-dihydroxyuracil (isodialuric acid or dialuric acid) were identified in OsO4-treated DNA. It is suggested that 5-hydroxyuracil was formed by formic acid-induced deamination and dehydration of cytosine glycol, which was the actual oxidation product of the cytosine moiety in DNA. 5-Hydroxycytosine obviously resulted from dehydration of cytosine glycol, and 5,6-dihydroxyuracil from deamination of 5,6-dihydroxycytosine. This scheme was supported by the presence of 5-hydroxyuracil, uracil glycol and 5,6-dihydroxyuracil in OsO4-treated cytosine. Treatment of OsO4-treated cytosine with formic acid caused the complete conversion of uracil glycol into 5-hydroxyuracil. The implications of these findings relative to studies of DNA repair are discussed.

Thymine glycol lesions terminate chain elongation by DNA polymerase I in vitro

Single-strand circular DNA from bacteriophage M13mp9 was chemically modified with osmium tetroxide to introduce specifically cis-thymine glycol lesions, a major type of DNA damage produced by ionizing radiation. An oligonucleotide primer was extended on damaged and undamaged templates using either the large fragment of E. coli pol I or T4 DNA polymerase. The reaction products were analysed by electrophoresis alongside a DNA sequence ladder. Synthesis on the damaged templates terminated at positions opposite thymine bases in the template. These results indicate that cis-thymine glycol lesions in single-strand DNA constitute blocks to synthesis by DNA polymerases in vitro. Surprisingly, replication halts after the correct nucleotide, dAMP, is inserted opposite the lesion. These results imply that the primary effect of the thymine glycol lesion is suppression of DNA synthesis and that the lesion is not a potent mutagen.

Sequence dependence for bypass of thymine glycols in DNA by DNA polymerase I

Single-stranded phage DNAs containing thymine glycols were prepared by oxidation with osmium tetroxide (OsO4) and were used as templates for DNA synthesis by E. coli DNA polymerase I. The induction of thymine glycol lesions in DNA, as measured by immunoassay, quantitatively accounted for an inhibition of in vitro DNA synthesis on modified templates. Analysis of termination sites for synthesis by DNA polymerase I (Klenow fragment) showed that DNA synthesis terminated at most template thymine sites in OsO4-treated DNA, indicating that incorporation occurred opposite putative thymine glycols in DNA. Nucleotides 5' and 3' to putative thymine glycol sites affect the reaction, however, since termination was not observed at thymines in the sequence 5'-CTPur-3'. Conversion of thymine glycols to urea residues in DNA by alkali treatment caused termination of DNA synthesis one nucleotide 3' to template thymine sites, including thymines in the 5'-CTPur-3' sequence, showing that the effect of surrounding sequence is on the elongation reaction by DNA polymerase rather than differential damage induction by OsO4.

Thymine glycols and urea residues in M13 DNA constitute replicative blocks in vitro

Thymine glycols were produced in M13 DNA in a concentration dependent manner by treating the DNA with osmium tetroxide (OsO4). For the formation of urea-containing M13 DNA, OsO4-oxidized DNA was hydrolyzed in alkali (pH 12) to convert the thymine glycols to urea residues. With both thymine glycol- and urea-containing M13 DNA, DNA synthesis catalyzed by Escherichia coli DNA polymerase I Klenow fragment was decreased in proportion to the number of damages present in the template DNA. Sequencing gel analysis of the products synthesized by E. coli DNA polymerase I and T4 DNA polymerase showed that DNA synthesis terminated opposite the putative thymine glycol site and at one nucleotide before the putative urea site. Substitution of manganese for magnesium in the reaction mix resulted in increased processivity of DNA synthesis so that a base was incorporated opposite urea. With thymine glycol-containing DNA, processivity in the presence of manganese was strongly dependent on the presence of a pyrimidine 5' to the thymine glycol in the template.

Thymine glycol and thymidine glycol in human and rat urine: a possible assay for oxidative DNA damage

Thymine glycol is a DNA damage product of ionizing radiation and other oxidative mutagens. In an attempt to find a noninvasive assay for oxidative DNA damage in individuals, we have developed an HPLC assay for free thymine glycol and thymidine glycol in urine. Our results indicate that humans excrete about 32 nmol of the two glycols per day. Rats, which have a higher specific metabolic rate and a shorter life span, excrete about 15 times more thymine glycol plus thymidine glycol per kg of body weight than do humans. We present evidence that thymine glycol and thymidine glycol are likely to be derived from repair of oxidized DNA, rather than from alternative sources such as the diet or bacterial flora. This noninvasive assay of DNA oxidation products may allow the direct testing of current theories which relate oxidative metabolism to the processes of aging and cancer in man.

Identification of the cis-thymine glycol moiety in chemically oxidized and gamma-irradiated deoxyribonucleic acid by high-pressure liquid chromatography analysis

5,6-Dihydroxy-5,6-dihydrothymine (thymine glycol) is formed in DNA by chemical oxidants and ionizing radiation. We describe the separation of thymine glycol, 5,6-dihydroxy-5,6-dihydrothymidine (thymidine glycol), thymine, and thymidine by high-pressure liquid chromatography (HPLC). Enzymatic hydrolysates of chemically oxidized or gamma-irradiated single-stranded DNA were cochromatographed with 14C-containing marker compounds. In chemically oxidized DNA, thymidine glycol was the major derivative formed. In addition, there were four rapidly eluting thymine-derived components. In irradiated DNA, thymidine glycol constituted about 5% of the modified thymines, and the rapidly eluting fractions were proportionately increased. DNA isolated from gamma-irradiated and nonirradiated HeLa cells grown in the presence of [3H]thymidine was subjected to enzymatic hydrolysis and HPLC analysis. In control DNA, 0.3% of the thymines were modified. Thirty-six kilorads of gamma radiation caused a 30% increase in thymine damage. Thus, most of the base damage was due to internal beta radiation from incorporated [3H]thymidine. The chromatographic patterns of irradiated and nonirradiated samples were qualitatively the same, but the yields of some products increased 2-fold, while others remained unchanged. A comparison of the HPLC profiles of hydrolysates of in vitro oxidized and irradiated DNA with those of the cellular DNA revealed one fast eluting peak to be absent in cellular DNA, suggesting that it was formed only in single-stranded DNA. In cellular DNA, the major modified thymine was a more hydrophobic derivative not formed by in vitro radiation nor chemical oxidation. As in in vitro irradiated DNA, thymidine glycol constituted 5% of the modified thymines. The presence of cis-thymidine glycol in hydrolysates was confirmed by chromatography on Sephadex LH-20 using water and borate as eluants.

Characterization of radiation damage to DNA by reaction with borohydride

Irradiation of aqueous solutions of native calf thymus DNA with x-rays produced functional groups that reacted with sodium borohydride. The DNA was labeled with tritium from NaB3H4 to the extent of 2.0 x 10(-10) atom/dalton/rad. The presence of cysteamine or other radical scavengers, or saturation of the solution with nitrogen during irradiation decreased the labeling. After mild acid hydrolysis, the major tritium-containing moiety was identical with 2,3-dihydroxy-2-methylpropanoic acid in all chromatographic systems tested. The suggested mechanism of labeling involved reduction by borohydride of the potential aldehyde at carbon 6 of thymine glycol residues present in the irradiated DNA.

Purification and properties of a mouse-cell DNA-repair endonuclease, which recognizes lesions in DNA induced by ultraviolet light, depurination, gamma-rays, and OsO4 treatment

A DNA-repair endonuclease has been purified 117-fold from mouse plasmacytoma cells (line MPC-11) by gel filtration, followed by ion-exchange and affinity chromatography. Its molecular weight was determined by gel filtration to be 28,000 +/- 2000. The enzyme recognizes apurinic and apyrimidinic sites induced by acid and gamma-rays in DNA, as well as another type of lesion(s) which is introduced into DNA by both ultraviolet irradiation and OsO4. Quantitative measurements of the number of nicks the purified DNA-repair endonuclease makes in DNA treated with various amounts of OsO4 and ultraviolet light suggests that the endonuclease may act on 5,6-dihydroxydihydrothymine lesions. The endonuclease activity was sensitive to the ionic strength and was most active in the presence of 100 mM KCl, whereas the presence of divalent cations did not stimulate the activity.

DNA N-glycosylases and UV repair

Repair of some DNA photoproducts can be mediated by glycosylic bond hydrolysis. Thus, Escherichia coli endonuclease III releases 5,6-hydrated thymines as free bases, while T4 UV endonuclease releases one of two glycosylic bonds holding pyrimidine dimers in DNA. In contrast, uninfected E. coli apparently does not excise pyrimidine dimers via a DNA glycosylase.

Damage to E. coli cells induced by tritium decay: secondary lethality under nongrowth conditions

Cells containing incorporated 3H-thymidine are damaged by its decay. It was found with E. coli TAU-bar cells that a small part of the damage is lethal whereas most of it is reparable and only potentially lethal. If cells are subjected to nongrowth conditions, the potentially lethal damage changes to lethal damage. This process is called secondary lethality (SL). The extent of SL and some changes in DNA under three different modes of growth inhibition were determined. It was found that: (i) SL is maximal under conditions of amino acid starvation (-AA), the viable count decreasing by two orders of magnitude. (ii) SL is 4 times lower in the presence of chloramphenicol (-AA + CLP) and 6.5 times lower under + AA + CLP conditions. Changes in the sedimentation rate of DNA determined in alkaline sucrose gradient correlate with the differences in SL: under -AA conditions the sedimentation rate of DNA decreases whereas in the presence of CLP no decrease occurs. The results suggest that certain enzymatic processes take place under -AA conditions which lead to irreparable changes in DNA.

Characteristics of excision repair of pyrimidine dimers in eukaryotic cells as assayed with anti-dimer sera

An antiserum that recognizes the three types of pyrimidine dimers induced by UV-light in DNA was used to monitor their removal from eukaryotic cell nuclei. Cells able to excise dimers display a similar removal pattern: a fast process completed within a few hours leaving many dimers in the DNA.

The nucleotide-permeable Escherichia coli cell, a sensitive DNA repair indicator for carcinogens, mutagens, and antitumor agents binding covalently to DNA

Ether-permeabilized (nucleotide-permeable) Escherichia coli cells respond to alkylating and arylalkylating carcinogens with DNA excision repair, as assessed by their stimulation of DNA repair synthesis. In the present work, we have investigated whether DNA repair synthesis in ether-treated E. coli cells can serve as a general indicator to monitor the DNA-binding of carcinogens, mutagens and antitumor agents. Therefore, a standard assay was developed and comparative analyses were performed on 11 ultimate carcinogens, 10 proximate carcinogens, 2 tumor promoters, 6 mutagens, and 12 antitumor agents. All ultimate carcinogens (alkylating, acylating, arylalkylating agents) and mutagens (e.g., hydrogeen peroxide, acridine derivatives) caused DNA excision repair in wild type cells as measured by [3H] dTMP incorporation and simultaneously inhibited replicative DNA synthesis to various extents. Control experiments with the mutant cells uvrA and uvrB were performed to determine whether the pyrimidine-dimer-specific UV-endonuclease was involved in the removal of DNA damage. This was found to be true for the ultimate carcinogens (Ac)2 ONFln, mitomycin C, and for very reactive alkylating carcinogens. None of the ultimate carcinogens induced repair polymerization in mutant cells lacking the 5'-3' exonucleolytic activity of DNA polymerase I. Proximate carcinogens, such as Me2NNO, 4-nitroquinoline-1-oxide and aflatoxins, did not induce excision repair in the standard assay, probably because of the inability of E. coli to perform the activation steps necessary for covalent DNA-binding. However, Me2NNO, when pretreated with Udenfriend's hydroxylating mixture, gave rise to a low level of repair polymerization in ether-treated cells. Intercalating mutagens, such as quinacrine and ethidum bromide, inhibited replicative DNA synthesis. However, they were not found to be repair-inducers. THE TUMOR PROMOters TPA and phorbol-12,13-didecanoate did not cause excision repair, even when applied at high concentrations, nor did they inhibit repair synthesis stimulated by MeNOUr or (Ac)2 ONFln. The antitumor agents may be classified into two groups on the basis of the influence they exert on DNA synthesis: members of the first group (involving BCNU and bleomycin) stimulate repair polymerization and, in addition, inhibit DNA replication. These compounds are known to bind covalently to DNA. The second group of drugs (including adriamycin and cis-Pt(II)diammine complexes) inhibits DNA replication without stimulating repair synthesis. The predominant DNA-interaction of these compounds is known to be a non-covalent (i.e., intercalative, electrostatic) binding. Our experiments show that the ether-permeabilized E. coli cell can be successfully used to test ultimate carcinogens, mutagens and antitumor agents for repair-inducing and replication-inhibiting activity. The standard test might be extended to pre- and proximate carcinogens, provided these can be suitably activated.

Molecular biology of the response of cells to radiation and to radiomimetic chemicals

Radiation and radiomimetic chemicals can be both carcinostatic and also carcinogenic and mutagenic. In all cases the critical reaction is with the cellular DNA in which both ionizing radiation and radiomimetic chemicals produce a variety of adducts and changes. Human cells respond to these lesions in several ways. Some adducts are ignored. Other are recognized as different by the excision repair mechanism and are cut out of the DNA. Other adducts may be by-passed by special post-replication repair mechanisms so that viable daughter cells still containing altered DNA are produced. Unrepaired lesions may lead to chromosome aberrations and cell death. Since only viable cells can produce tumors, post replication repair is critical to the initial events in carcinogenesis. Lesions which are converted to DNA strand breaks, on the other hand, lead to cell death. Knowledge of the changes produced in DNA and understanding of the different cellular responses possible should permit prediction of the relative tumorigenic and tumoristatic properties of compounds.

Influence of a uvrD mutation on survival and repair of X-irradiated Escherichia coli K-12 cells

The presence of a uvrD mutation increased the X-ray sensitivities of E. coli wild-type and polA strains, but had no effect on the sensitivities of recA and recB strains, and little effect on a lexA strain. Incubation of irradiated cells in medium containing 2,4-dinitrophenol or chloramphenicol decreased the survival of wild-type and uvrD cells, but had no effect on the survival of recA, recB and lexA strains. Alkaline sucrose gradient sedimentation studies indicated that the uvrD strain is deficient in the growth-medium-dependent (Type III) repair of DNA single-strand breaks. These results indicate that the uvrD mutation inhibits certain rec+lex+-dependent repair processes, including the growth-medium-dependent (Type III) repair of X-ray-induced DNA single-strand breaks, but does not inhibit other rec+lex+-dependent processes that are sensitive to 2,4-dinitrophenol and chloramphenicol.

Deoxyribonucleic acid repair in vitro by extracts of Escherichia coli

Deoxyribonucleic acid (DNA) from bacteriophage T7 has been used to monitor the capacity of gently lysed extracts of Escherichia coli to perform repair resynthesis after ultraviolet (UV) irradiation. Purified DNA damaged by up to 100 J of UV radiation per m2 was treated with an endonuclease from Micrococcus luteus that introduces single-strand breaks in irradiated DNA. This DNA was then used as a substrate to study repair resynthesis by extracts of E. coli. It was found that incubation with the extract and exogenous nucleoside triphosphates under suitable assay conditions resulted in removal of all pyrimidine dimers and restoration of the substrate DNA to its original molecular weight. Repair resynthesis, detected as nonconservative, UV-stimulated DNA synthesis, was directly proportional tothe number of pyrimidine dimers introduced by radiation. The repair mode described here appears to require DNA polymerase I since it does no occur at the restrictive temperature in polA12 mutants, which contain a thermolabile polymerase. The addition of purified DNA polymerase I to extracts made from a polA mutant restores the ability to complete repair at the restrictive temperature.

Deficiency of gamma-ray excision repair in skin fibroblasts from patients with Fanconi's anemia

The capacity of preparations of skin fibroblasts from normal individuals and patients with Fanconi's anemia to excise gamma-ray products of the 5,6-dihydroxydihydrothymine type from exogenous DNA was investigated. The excision capacity of whole-cell homogenates of fibroblasts from two of four patients with Fanconi's anemia was substantially below normal. This repair deficiency was further pronounced in nuclear preparations from cells of the same two patients.

Lethality and double-strand scissions from 14C decay in the DNA of micro-organisms

14C-2-thymidine was incorporated into the DNA of E. coli B/r and of coliphage T4. The labelled organisms were stored for several years at -196 degrees C. Both were periodically assayed for loss of viability, and the coliphage also for the appearance of double-strand breaks (DSBs) in DNA. E. coli B/r exhibited a survival curve with a substantial initial shoulder, extrapolation number 5-2 +/- 2-3, and a final exponential portion corresponding to a lethal efficiency per 14C decay per 2-5 X 10(9) daltons of DNA, of 0-009 +/- 0-002. For coliphage T4, our best estimate for the lethal efficiency per 14C decay is 0-03 +/- 0-04, and that for the DNA breakage efficiency is -0-002 +/- 0-004. The large standard errors result from the very small number of 14C decays occurring in each phage. These results suggest that 14C decay in the DNA of micro-organisms does not cause DSBs but does cause potentially lethal damage to the thymine bases in which decay occurs, and that wild-type E. coli can repair a large number of such DNA lesions.

Enzymatic induction of DNA double-strand breaks in gamma-irradiated Escherichia coli K-12

The polA1 mutation increases the sensitivity of E. coli K-12 by killing by gamma-irradiation in air by a factor of 2.9 and increases the yield of DNA double-strand breaks by a factor of 2.5. These additional DNA double-strand breaks appear to be due to the action of nucleases in the polA1 strain rather than to the rejoining of radiation-induced double-strand breaks in the pol+ strain. This conclusion is based upon the observation that gamma-irradiation at 3 degrees did not affect the yield of DNA double-strand breaks in the pol+ strain, but decreased the yield in the polA1 strain by a factor of 2.2. Irradiation of the polA1 strain at 3 degrees followed by incubation at 3 degrees for 20 min before plating resulted in approximately a 1.5-fold increase in the D0. The yield of DNA double-strand breaks was reduced by a factor of 1.5. The pol+ strain, however, did not show the protective effect of the low temperature incubation upon either survival or DNA double-strand breakage. We suggest that the increased yield of DNA double-strand breaks in the polA1 strain may be the result of the unsuccessful exision repair of ionizing radiation-induced DNA base damage.

Excision-repair of gamma-ray-damaged thymine in bacterial and and mammalian systems

The selective excision of products of the 5,6-dihydroxy-dihydrothymine type (t') from gamma-irradiated or OSO4-oxidized DNA or synthetic poly[d(A-T)] was observed with crude extracts of Escherichia coli and isolated nuclei from human carcinoma HeLa S-3 and Chinese hamster ovary cells. The results with E. coli extracts allow the following conclusion: (1) The uvrA-gene product is not required for t' excision. (2) Radiation-induced strand breakage is not required for product excision. (3) Experiments with extracts of E. coli polAexl showed that the 5' in equilibrium 3' exonuclease associated with polymerase I is responsible for the removal of t'. (4) Experiments with extracts of E. coli endo I lig 4 and the ligase inhibitor nicotinamide mononucleotide showed that polynucleotide ligase accomplishes the last strand resealing step in the excision-repair of t'. Isolated nuclei from HeLa and Chinese hamster ovary cells possess the necessary enzymes for the selective excision of t' from gamma-irradiated or osmium tetroxide oxidized DNA. Approximately 25 to 35% of the products were removed from DNA within 60 min. Unspecific DNA degradation was very low. Radiation-induced strand breakage is not required for product removal.