Neutral sucrose gradient sedimentation of very large DNA from Bacillus subtilis. II. Double-strand breaks formed by gamma ray irradiation of the cells

A procedure has been developed whereby essentially all the DNA from Bacillus subtilis cells can be reproducibly extracted in a form which sediments 2.3 times faster than bacteriophage T2 DNA in a neutral sucrose gradient spun at 20,000 revs/ min. When the cells are irradiated with low (3 to 34 kilorads) gamma ray doses, some DNA moves in a slower peak, which from the previous paper (Levin &; Hutchinson, 1973) appears to be linear DNA. Some of the DNA also sediments ahead of the unirradiated DNA. On incubation of the cells at 37°C under conditions such that single-strand DNA breaks are repaired, the fast-sedimenting component is partially restored, with the DNA sedimenting ahead of it usually disappearing, and the quantity in the slower component decreasing. With 80 minutes incubation the fraction of DNA after various radiation doses in the fast-sedimenting component is the same as the fraction of cells able to form colonies, suggesting that the destruction of the component is responsible for the effect of gamma rays on the ability of a cell to replicate. Single-strand breaks introduced into the DNA within the cells do not affect the fast-sedimenting component, so radiation-induced single-strand breaks are not responsible for the effect of gamma rays on replication.The double-strand break rate for DNA in the cells is 0.010 breaks per mass the size of T2 DNA per kilorad. The fast-sedimenting component in irradiated cells which have not been incubated disappears at a rate equal to one radiationinduced double-strand break formed per genome. Since the fast-sedimenting component in solution is also destroyed by one double-strand break per genome (Levin &; Hutchinson, 1973), it is suggested that this component is the genome in the form of a circle. The correspondence between DNA in the fast-sedimenting form after incubation and the ability of cells to form colonies then indicates that a genome can replicate only if all double-strand breaks are repaired.     

In Vitro Repair of Gaps in Bacteriophage T7 DNA

An in vitro system based upon extracts of Escherichia coli infected with bacteriophage T7 was used to study the mechanism of double-strand break repair. Double-strand breaks were placed in T7 genomes by cutting with a restriction endonuclease which recognizes a unique site in the T7 genome. These molecules were allowed to repair under conditions where the double-strand break could be healed by (i) direct joining of the two partial genomes resulting from the break, (ii) annealing of complementary versions of 17-bp sequences repeated on either side of the break, or (iii) recombination with intact T7 DNA molecules. The data show that while direct joining and single-strand annealing contributed to repair of double-strand breaks, these mechanisms made only minor contributions. The efficiency of repair was greatly enhanced when DNA molecules that bridge the region of the double-strand break (referred to as donor DNA) were provided in the reaction mixtures. Moreover, in the presence of the donor DNA most of the repaired molecules acquired genetic markers from the donor DNA, implying that recombination between the DNA molecules was instrumental in repairing the break. Double-strand break repair in this system is highly efficient, with more than 50% of the broken molecules being repaired within 30 min under some experimental conditions. Gaps of 1,600 nucleotides were repaired nearly as well as simple double-strand breaks. Perfect homology between the DNA sequence near the break site and the donor DNA resulted in minor (twofold) improvement in the efficiency of repair. However, double-strand break repair was still highly efficient when there were inhomogeneities between the ends created by the double-strand break and the T7 genome or between the ends of the donor DNA molecules and the genome. The distance between the double-strand break and the ends of the donor DNA molecule was critical to the repair efficiency. The data argue that ends of DNA molecules formed by double-strand breaks are typically digested by between 150 and 500 nucleotides to form a gap that is subsequently repaired by recombination with other DNA molecules present in the same reaction mixture or infected cell.     

Gamma-ray induced double-strand breaks in DNA resulting from randomly-inflicted single-strand breaks: temporal local denaturation, a new radiation phenomenon?

The induction of single- and double-strand breaks in DNA by gamma-rays has been measured. The maximum number of nucleotide pairs (a) between two independently induced single-strand breaks in opposite strands of the DNA which cannot prevent the occurrence of a double-strand break was found to amount to about 16. This value did not differ significantly for the four types of bacteriophage DNA investigated (T4, T7 and PM2 DNA, and replicative form DNA of phage phiX174) and was the same in 10(-2) M phosphate buffer containing 0, 0.5 or 1 M NaCl. In 10(-3) M phosphate buffer a was 34 nucleotide pairs. Evidence is presented that the relatively large value of a has to be ascribed at least partly to a temporal local denaturation accompanying the induction of a single-strand scission. A contribution of base damage that labilizes the DNA-helix, between two single-strand breaks to the high value of a can not be excluded.     

Correlation between Unrepaired Radiation-induced DNA Strand Breaks and Mitotic Delay in <Emphasis Type="Italic">Physarum polycephalum</Emphasis>

THE DNA of cells exposed to ionizing radiation incurs strand breaks and certain other types of damage (for review see ref. 1). Single-strand breaks are repaired both in prokaryotes^2,3 and in eukaryotes^4–6. But although double-strand break repair has been reported for phage DNA in lambda phage-infected bacteria⁷, for the radioresistant bacterium Micrococcus radiodurans⁸ and for the Chinese hamster ovary cell⁹, this type of repair has not been demonstrated in other bacterial species³ and mammalian cell lines^5,6,10, suggesting that double-strand, rather than single-strand breaks are the lesions primarily responsible for the lethal effects of ionizing radiation^3,6,11.     

Rapid inactivation of bacteriophage T7 by ascorbic acid is repairable

Treatment of bacteriophage T7 with ascorbic acid resulted in the rapid accumulation of single-strand breaks in the DNA with double-strand breaks appearing only after incubation times of 20 min or longer. The single-strand breaks were responsible for a rapid inactivation of the phage as assayed by immediate plating of the phage-bacteria mixture on nutrient agar. Incubation of the phage-bacteria mixture in liquid medium prior to plating allowed a host cell reactivation process to repair the nicks and reactivate the phage. Non-reversible inactivation of the phage was a slower process which could be correlated with the appearance of double-strand breaks in the phage DNA. Host cell reactivation of the phage was also manifested in the phenomena of delayed lysis and delayed appearance of the concatemeric DNA replication intermediate.     

DNA damage and repair in relation to cell killing in neocarzinostatin-treated HeLa cells.

To elucidate the mechanism of the cell killing activity of neocarzinostatin on mammalian cells, the drug-induced damage of DNA and its repair were examined. Very low doses of neocarzinostatin, at which high survival of cells was observed, clearly produced single-strand breaks of DNA and decomposition of the 'DNA complex', but these damages appeared to be repaired almost completely. At higher doses of neocarzinostatin, single-strand breaks were repaired to a considerable extent while double-strand breaks seemed not to be repaired. The number of non-repairable single-strand breaks was about twice that of double-strand breaks. This implies that single-strand breaks are repaired except for those constituting double-strand breaks. Although at low levels of neocarzinostatin repair of double-strand breaks may occur, the correlation existing between the colony-forming ability of cells treated with neocarzinostatin and non-repairable DNA breakage suggests that production of a small number of critical non-repairable double-strand breaks per cell may be responsible for the cell killing activity of the drug.     

Escherichia coli radC is deficient in the recA-dependent repair of X-ray-induced DNA strand breaks

Escherichia coli K-12 cells incubated in buffer can repair most of their X-ray-induced DNA single-strand breaks, but additional single-strand breaks are repaired when the cells are incubated in growth medium. While the radC102 mutant was proficient at repairing DNA single-strand breaks in buffer (polA-dependent repair), it was partially deficient in repairing the additional single-strand breaks (or alkali-labile lesions) that the wild-type strain can repair in growth medium (recA-dependent repair), and this repair deficiency correlated with the X-ray survival deficiency of the radC strain. In studies using neutral sucrose gradients, the radC strain consistently showed a small deficiency in rejoining X-ray-induced DNA double-strand breaks, and it was deficient in restoring the normal sedimentation characteristics of the repaired DNA.     

DNA strand break and rejoining in cultured human fibroblasts exposed to fast neutrons or gamma rays

The production and rejoining of DNA single-strand and double-strand breaks have been monitored in monolayer cultures of proliferating human skin fibroblasts by means of sensitive techniques. Cells were irradiated with low doses of either 60Co gamma-rays or 14.6 MeV neutrons at 0 degrees C (0-5 Gy for measurement of single-strand breaks by alkaline elution and 0-50 Gy for double-strand breaks measured by neutral elution). The yield of single-strand breaks induced by neutrons was 30 per cent of that produced by the same dose of gamma-rays; whilst in the induction of double-strand breaks neutrons were 1.6 times as effective as gamma-rays. Upon post-irradiation incubation of cells at 37 degrees C, neutron-induced single-strand and double-strand breaks were rejoined with a similar time-course to gamma-induced breaks. Rejoining followed biphasic kinetics; of the single-strand breaks, 50 per cent disappeared within 2 min after gamma-rays and 6-10 min after neutrons. Fifty per cent of the double-strand breaks disappeared within 10 min, after gamma-rays and neutrons. Cells derived from patients suffering from ataxia-telangiectasia showed the same capacity for repair of single- and double-strand breaks induced by 14.6 MeV neutrons, as cells established from normal donors. The comparison of neutrons and gamma-rays in the induction of DNA breaks did not explain the elevated r.b.e. on high LET radiation. However, a study of the variation in the spectrum of lesions induced by different radiation sources will probably contribute to the clarification of the relative importance of other radio products.     

Comparison of the resA1 and polA1 Mutations in Isogenic Strains of Escherichia coli K-12

Strains carrying either the polA1 or resA1 mutation are deficient in DNA polymerase I, and the polA1 and resA1 mutations do not complement in merozygotes. The effect of these mutations in otherwise identical genetic backgrounds was studied: after ultraviolet irradiation both strains degrade their DNA more rapidly and more extensively than the wild-type strains. However, after X-ray irradiation the resA1 strain shows little DNA breakdown and repairs its single-strand breaks. In contrast, the polA1 strain degrades its DNA extensively, and single-strand breaks are not repaired. Moreover, the resA1 strain is capable of supporting the growth of a red(-) bacteriophage lambda, whereas the polA1 strain is not.     

Site specificity of bleomycin-mediated single-strand scissions and alkali-labile damage in duplex DNA.

Form II PM2 DNA, which contained bleomycin-mediated single-strand breaks, was purified and treated with the extracellular endonuclease from Alteromonas BAL 31. This enzyme cleaves the phosphodiester backbone opposite a single-strand break to yield a double-strand break. The locations of these double-strand breaks were determined relative to the cleavage sites produced by the restriction enzyme HindIII. The experimental procedure was as follows. Form I PM2 DNA was treated with bleomycin to produce alkali-labile bonds. These were hydrolyzed by alkali treatment and the DNA, now containing single-strand breaks, was purified and treated with the BAL 31 enzyme and the HindIII enzyme to determine the positions of the original alkali-labile bonds. It was found that the single-strand breaks and alkali-labile bonds were introduced at preferred sites on the PM2 genome, since electrophoretic analyses of the DNA after the HindIII digestion revealed DNA bands of discrete sizes. The molecular weights of the DNA fragments produced by these treatments indicate that single-strand breaks and alkali-labile bonds occur at the same sites as those previously determined for direct double-strand scissions introduced by bleomycin at neutral pH. Some of the specific sites of double-strand scissions mediated by bleomycin at neutral pH (Lloyd et al., 1978b) are also shown here to be relatively more reactive than other sites when the DNA contains superhelical turns.     

Iodine-125 decay in a synthetic oligodeoxynucleotide. I. Fragment size distribution and evaluation of breakage probability

Lobachevsky, P. N. and Martin, R. F. Iodine-125 Decay in a Synthetic Oligodeoxynucleotide. I. Fragment Size Distribution and Evaluation of Breakage Probability. Incorporation of (125)I-dC into a defined location of a double-stranded oligodeoxynucleotide was used to investigate DNA breaks arising from decay of the Auger electron-emitting isotope. Samples of the oligodeoxynucleotide were also labeled with (32)P at either the 5' or 3' end of either the (125)I-dC-containing (so-called top) or opposite (bottom) strand and incubated in 20 mM phosphate buffer or the same buffer plus 2 M dimethylsulfoxide at 4 degrees C during 18-20 days. The (32)P-end-labeled fragments produced by (125)I decays were separated on denaturing polyacrylamide gels, and the (32)P activity in each fragment was determined by scintillation counting after elution of fragments from the gel. The relative fragment size distributions were then normalized on a per decay basis and converted to a distribution of single-strand break probabilities as a function of distance from the (125)I-dC. The results of three to five experiments for each of eight possible combinations of labels and incubation conditions are presented as a table showing the relative numbers of (32)P counts in different fragments as well as graphs of normalized fragment size distributions and probabilities of breakage. The average numbers of single-strand breaks per (125)I decay are 3. 3 and 3.7 in the top strand and 1.3 and 1.5 in the bottom strand with and without dimethylsulfoxide, respectively. Every (125)I decay event produces a break in the top strand, and breakage of the bottom strand occurs in 75-80% of the events. Thus a double-strand break is produced by (125)I decay with a probability of approximately 0.8.     

Securing genome stability by orchestrating DNA repair: removal of radiation-induced clustered lesions in DNA

In addition to double- and single-strand DNA breaks and isolated base modifications, ionizing radiation induces clustered DNA damage, which contains two or more lesions closely spaced within about two helical turns on opposite DNA strands. Post-irradiation repair of single-base lesions is routinely performed by base excision repair and a DNA strand break is involved as an intermediate. Simultaneous processing of lesions on opposite DNA strands may generate double-strand DNA breaks and enhance nonhomologous end joining, which frequently results in the formation of deletions. Recent studies support the possibility that the mechanism of base excision repair contributes to genome stability by diminishing the formation of double-strand DNA breaks during processing of clustered lesions.     

Ionizing radiation damage to the folded chromosome of Escherichia coli K-12: sedimentation properties of irradiated nucleoids and chromosomal deoxyribonucleic acid.

The structures of the membrane-free nucleoid of Escherichia coli K-12 and of unfolded chromosomal deoxyribonucleic acid (DNA) were investigated by low-speed sedimentation on neutral sucrose gradients after irradiation with 60Co gamma rays. Irradiation both in vivo and in vitro was used as a molecular probe of the constraints on DNA packaging in the bacterial chromosome. The number of domains of supercoiling was estimated to be approximately 180 per genome equivalent of DNA, based on measurements of relaxation caused by single-strand break formation in folded chromosomes gamma irradiated in vivo and in vitro. Similar estimates based on the target size of ribonucleic acid molecules responsible for maintaining the compact packaging of the nucleoid predicted negligible unfolding due to the formation of ribonucleic acid single-strand breaks at doses of up to 10 krad; this was born out by experimental measurements. Unfolding of the nucleoid in vitro by limit digestion with ribonuclease or by heating at 70 degrees C resulted in DNA complexes with sedimentation coefficients of 1,030 +/- 59S and 625 +/- 15S, respectively. The difference in these rates was apparently due to more complete deproteinization and thus less mass in the heated material. These structures are believed to represent intact, replicating genomes in the form of complex-theta structures containing two to three genome equivalents of DNA. The rate of formation of double-strand breaks was determined from molecular weight measurements of thermally unfolded chromosomal DNA gamma irradiated in vitro. Break formation was linear with doses up to 10 krad and occurred at a rate of 0.27 double-strand break per krad per genome equivalent of DNA (1,080 eV/double-strand break). The influence of possible nonlinear DNA conformations on these values is discussed.     

The influence of oxygen on the survival and yield of DNA double-strand breaks in irradiated yeast cells.

Survival and induction of DNA double-strand breaks were studied in cells of Saccharomyces cerevisiae irradiated under oxic or anoxic conditions with 30 MeV electrons. A linear relationship between DNA double-strand breakage and dose was found in both cases. The o.e.r.-value for colony forming ability was found to be 1.9 +/- 0.2, whereas the o.e.r.-value for DNA double-strand breakage was 3.0 +/- 0.1. These results are not inconsistent with the idea that DNA double-strand breaks are involved in killing of yeast cells. The frequency of induction of DNA double-strand breaks was found to be 0.74 x 10(-11) double-strand breaks per g/mol per Gy when cells were irradiated under oxygen and 0.24 x 10(-11) double-strand breaks per g/mol per Gy under nitrogen.     

Double-strand breaks from single photochemical events in DNA containing 5-bromouracil.

Ultraviolet irradiation of Escherichia coli cells with a low level of 5-bromouracil incorporated produces DNA double-strand breaks by single photochemical events, one such break per 100 single-strand breaks, the latter assayed in alkali-denatured DNA. About 2.5--4 double-strand breaks are produced per "lethal hit," compared with about 6 double-strand breaks per lethal hit induced by gamma rays. These results are consistent with the hypothesis that an unrepaired DNA double-strand break is a major lethal event in both cases. The increase in sensitivity to ultraviolet (measured by colony-forming ability) seems linear in the number of bromouracils incorporated (0--20% of the thymines), and the linear relationship is much the same for incorporation in one or in both strands of the DNA double helix.     

Radiation-induced strand breaks in phi X174 replicative form DNA: an improved experimental and theoretical approach

To determine the yield of radiation-induced single-strand, double-strand and potential breaks (breaks which are converted into actual breaks by alkali or heat treatment) oxygenated aqueous solutions of phi X174 supercoiled circular double-stranded (RFI) DNA were irradiated with increasing doses of gamma-irradiation and subjected to electrophoresis on agarose gels both before and after heat treatment. A complete separation was obtained of RFI, RFII (relaxed circle due to one or more single-strand breaks) and RFIII (linear DNA due to one double-strand break). A computer-assisted spectrophotometric procedure was developed, which enabled us to measure very accurately the amount of DNA present in the three DNA fractions. The quantitative changes of each fraction of DNA with dose could be fitted to a straightforward statistical model, which described the dose-dependent formation of the different types of breaks and from which the D37-values of single-strand, potential single-strand and double-strand breaks could be calculated to be 0.42 +/- 0.02, 1.40 +/- 0.25 and 57 +/- 36 Gy respectively. Potential double-strand breaks were not formed significantly under our conditions. In addition the maximum distance between two independently introduced single-strand breaks in opposite strands resulting in a double-strand break could be determined. The values before and after heat treatment are shown to be 29 +/- 6 and 102 +/- 13 nucleotides, respectively.     

The action of colicin E2 on supercoiled lambda DNA. I. Experiments in vivo.

A lambda DNA supercoil system has been developed to study the effects of colicin E2 on DNA in vivo. Colicin E2, a protein antibiotic synthesized by strains of coliform bacteria that carry the Col E2 plasmid, had as its most conspicious effect damage to the DNA of sensitive strains. Colicine E2 attacks the supercoiled molecul formed by labeled lambda DNA in superinfected cells as well as it attacks the bacterial DNA. The rate and extent of acid solubilization of the lambda supercoils and of host bacterial DNA induced by E2 treatment are nearly identical. Treatment of superinfected cells with colicin E2 results in the progressive conversion of lambda DNA supercoils to open circles and/or linear full lenght molecules, and subsequently to fragments less than full lambda in size. The first endonucleolytic reactions are single-strand and or double-strand breaks. The rate of supercoil breakdown as well as the final percent supercoils remaining unconverted, the size of the final lambda fragments, and the extent of solubilization are dependent on the multiplicity of colicin used. Additions of trypsin to E2-treated superinfected cells results in a cessation of further breakdown of the lambda molecules, presumably as a result of digestion of accessible colicin molecules. Energy is essential for an early event in colicin E2 action. The host enzymes, endonuclease I and Rec BC, may be instrumental in the nucleolytic process caused by colicin E2: endonuclease I in reaction preceding cell killing and Rec BC in a secondary degradation of the bacterial DNA.     

Role of genes 46 and 47 in bacteriophage T4 reproduction. II. Formation of gaps on parental DNA of polynucleotide ligase defective mutants

The nature of nucleolytic activity regulated by genes 46 and 47 of bacteriophage T4 was studied by examining the metabolism of parental DNA of phages carrying a mutation in polynucleotide ligase gene (lig) and an additional mutation in one of the following D0 genes (D0 genes are necessary for T4 DNA synthesis): 32, 43 (DNA polymerase  pol), 44 and 45. Polynucleotide ligase and DNA polymerase were used to distinguish nicks (phosphodiester bond interruptions on duplex DNA) from gaps (interruptions with missing nucleotides). In non-permissive hosts, parental DNA of double mutants (lig, D0) accumulated both single- and double-strand breaks. Up to 30% of this DNA eventually became acid-soluble. An additional mutation in gene 46 (or 47) did not prevent accumulation of double- and single-strand breaks but did prevent degradation to the acid-soluble state. The majority of the single-strand breaks on (lig, D0)-DNA were presumed to be gaps since, after extraction from infected host cells, they were repaired by ligase plus DNA polymerase but not by ligase alone. In contrast, the majority of the single-strand breaks on parental DNA of (lig, D0, 46) or (lig, pol, 47) were repaired by ligase alone, suggesting nicks, rather than gaps. These observations suggest that (i) genes 46 and 47 regulate, either directly or indirectly, an exonuelease activity which can attack T4 DNA at nicks to create gaps, and (ii) T4 DNA polymerase, and the products of genes 32, 44 and 45 are necessary to prevent nicks from becoming gaps in vivo. Possible roles for genes 46 and 47 in T4 DNA replication and in recombination are discussed.