Action of exonuclease III on γ-irradiated DNA

Detection of DNA strand breaks in gamma-irradiated lymphocytes using surface plasmon resonance

Surface plasmon resonance (SPR) is a sensitive, rapid, simple and low cost method for detection of biological molecules. In this study, SPR technology with alkaline phosphatase as a probe was utilized to measure DNA strand breaks induced by (60)Co gamma rays. The doses were from 0.01-10 Gy with a dose rate of 0.1 Gy/min. The results demonstrate that the SPR technology can be used to estimate strand breaks of calf thymus DNA. SPR signals of the calf thymus DNA samples increased with increasing gamma ray doses and the relationship of y = sqrt (3297x + 582.6) (r = 0.99) between the SPR signal and gamma dose was obtained. Estimation of DNA strand breaks in irradiated lymphocytes by SPR also demonstrated an increase in SPR signal with increasing dose and the exponential relationship of y = 169.43 × (1 - exp(-0.89x)) (r = 0.93) was obtained. The initial yield of the SPR signal is about 150.79 mdeg · Gy(-1) and compared to the sensitivity of 0.05 Gy achieved by the neutral single cell gel electrophoresis (SCGE), the SPR-based assay of DNA strand breaks was found to be more sensitive (0.02 Gy). We therefore propose that SPR technology with alkaline phosphatase as the probe is a sensitive, simple and quick method for detection of DNA strand breaks in gamma-irradiated lymphocytes.

Determination of radiation-induced DNA strand breaks in individual cells by non-radioactive labelling of 3' OH ends

To quantify DNA strand breaks generated by ionizing radiation in single cells with preserved morphology, the number of radiation-induced 3' OH ends of nuclear DNA was determined by enzymatic labelling. Confluent CHO-K1 cells were irradiated with doses up to 100 Gy. After fixation and permeabilization of the cell monolayer the nuclear DNA was labelled with Digoxigenin-11-dUTP using terminal transferase. The incorporated nucleotide was detected with an anti-Digoxigenin antibody conjugated with alkaline phosphatase. The phosphatase bound was quantified by a colour reaction and the integrated optical densities of the cell nuclei were measured. For doses ranging from 20 to 100 Gy a linear relationship between dose and labelling signal was obtained. Repair experiments showed a fast component of repair with a half-time of about 14 min, followed by a slower decline to background values, which were reached after 6-8 h. This method allows the measurement of radiation-induced DNA strand breaks in morphologically preserved single cells in a reproducible way, which may be of importance in the prediction of tumour response in radiotherapy.

Mechanisms of induction and repair of DNA double-strand breaks by ionizing radiation: some contradictions

The various aspects of formation and repair of radiation-induced double-strand breaks (DSB) are summarized. Concerning the structure of DSB found in irradiated cells, enzymatic and microdosimetric analysis hints at complex damage of the DNA structure at the position of a DSB. With increasing LET, the DSB damage may be more complex than that induced by low-LET irradiation. Most of the DSB are repaired in the irradiated cell; apparently the kinetics of DSB repair and the fraction of unrejoined DSB determine cell survival or cell death. We do not know the details of the complex machinery of DSB repair; certainly recombination processes are involved, but there are still contradictions between our current knowledge about the mechanisms of recombinational DSB repair and the observed kinetics.

Differential inhibition of mammalian DNA polymerases by X-irradiated DNA

Using mammalian DNA polymerases alpha, beta and terminal deoxynucleotidyl transferase, we have examined the inhibitory action of X-irradiated DNA on in vitro DNA synthetic activities of these enzymes. It was found that DNA polymerase beta was highly sensitive inhibition by the irradiated DNA as well as DNA polymerases I of E. coli, while DNA polymerase alpha was at least two hundred times more resistant to inhibition than DNA ploymerase beta. Terminal deoxynucleotidyl transferase was inhibited moderately by the single-stranded form of the irradiated DNA. Since the inhibition was competitive with respect to a template-initiator for all DNA polymerases or an initiator for terminal deoxynucleotidyl transferase, the differences in sensitivities to the inhibition may be due to the different affinities of the enzymes to the X-ray-induced inhibitory sites on the DNA strand.

Induction and repair of strand breaks and 3'-hydroxy terminals in the DNA of mouse brain following gamma irradiation

DNA was isolated from mouse brain after in vivo gamma-ray irradiation, treated with endonuclease S1 from Aspergillus oryzae if necessary, and analysed further by alkaline and neutral sucrose gradient centrifugation. In parallel, its template activity was determined by DNA polymerase (EC 2.7.7.7, enzyme A of Klenow from Escherichia coli) assay as described previously. Similar experiments were performed with cultured mouse leukaemia cells (L5178Y) irradiated in vitro at 0 degrees C. Irradiation induced single- and double-strand breaks in the DNA of the brain with a yield of 1.0 and 0.1 break per 10(12) dalton per rad (100 eV/break and 770 eV/break), respectively. The yield of single-strand breaks in the brain was lower than that found in the cultured cells, whereas the yield of double-strand breaks was found to be almost the same in both cases. Treatment of irradiated DNA with single-strand-specific S1 endonuclease gave rise to further breaks detected on neutral sucrose gradient analysis. The yield of these breaks was also higher in the brain compared to the cultured cells. The increase per unit dose in the template activity of the DNA from the brain was found to be five times as much as that found in the cultured cells. Then, the average number of deoxyribonucleotides incorporated per break was determined on DNA which had experienced different treatments. The value for the brain DNA irradiated in vivo was found to be five times as much as that found for DNA treated with pancreatic deoxyribonuclease and 10 times as much as those found for DNA from the cultured cells and isolated brain nuclei irradiated in vitro at 0 degrees C. Thus, in vivo irradiation seemed to induce gaps with 3'-OH terminals in addition to simple breaks with or without 3'-OH terminals found in the cultured cells. Radiation-induced single-strand breaks and 3'-OH terminals in the DNA of the brain were repaired following irradiation. Approx. 20--40% of the terminals or breaks induced were, however, remaining at 3 h or more after irradiation, depending on the dose administered.

Local perturbation of the double helical DNA structure near single breaks

The influences of DNA composition and solvent modification on the stability of the native DNA structure near a single break have been studied. The value of the magnification parameter h of the double helix breakdown probability in a haplotomic degradation process is used as an index of the perturbation range. Methodological and technical details are discussed and comments are made on previously reported data on the h value. From this study it may be concluded that the width of the perturbation zone next to a nick is influenced by solvent-induced changes in the general stability of the native DNA molecule, and by compositional-dependent local interactions. Our results point to entropic effects as the more important contributions to stability perturbation near a discontinuity in the native DNA molecule.

The activity of mammalian polynucleotide ligase on x-irradiated DNAs

Selected samples of heterogeneous DNA from calf thymus with similar number-average molecular weight, Mn, and a low incidence of single-strand breaks were exposed in aqueous solutions to a mild X-ray dose of 1500 rads. The irradiation produced on the average about 0.2 bihelical and 2.2 monohelical scissions per DNA molecule of 1708 000 Mn. The percent distribution of the chemical termini released at the radiation nicks of DNA was as follows: 64.0 OH, 9.0 PO4 and 27.0 unknowns at the 3' ends: 3.8 OH, 68.2 PO4 and 28.0 unknowns at the 5' ends. A nuclease-free polynucleotide ligase I purified about 3000-fold over the crude homogenate from calf thymus succeeded in rejoining 50% of the breaks in the X-irradiated DNA. The ability of the enzyme to close radiation nicks in DNA directly was confirmed also by experiments on synthetic poly(dA).poly([3H]dT),poly(dT)-cellulose substrates with an irradiated dT chain at either the 3' or the 5' side of the functional break. The poor discrimination of mammalian ligase versus nicked DNA containing radiation damage is of practical relevance. While rejoining altered nucleotide chains in the helices of DNA, the enzyme might contribute to the fixation of premutational lesions in the genetic material.

Action of intercalating agents on the activity of DNA polymerase I

The effect of intercalating compounds such as 9-aminoacridine, quinacrine (atebrin), proflavine and daunomycin on the activity of DNA polymerase I(EC 2.7.7.7) was studied in vitro and compared with the binding of these acridines to native DNA. The enzyme kinetics were followed at various concentrations of DNA 3'-OH primer end groups and constant concentrations of deoxynucleosidetriphosphates as well as under the opposite conditions. The Km values for the DNA 3'-OH end groups were 16--38 nM and for the deoxynucleosidetriphosphates 2--5 micrometer, depending on the buffer and pH used in the enzymatic assay. All acridine derivates inhibit the DNA polymerase; at variable DNA concentrations a competitive inhibition was observed, where the Ki values ranged between 0.87 and 8.5 micrometer. At variable concentrations of deoxynucleosidetriphosphates and constant DNA concentration a non-competitive inhibition was observed. On denatured 3'-OH DNA as well as on poly(dA) - (dT)10 as substrate no inhibition by 9-aminoacridine was observed. 5'--3' exonuclease activity of DNA polymerase is inhibited by 9-aminoacridine but 3'--5' exonuclease activity on denatured DNA is not influenced by this intercalating compound. The affinity of the acridines to DNA was determined spectrophotometrically under conditions similar to those in the enzymatic assay and the computed frequency of intercalation was related to the inhibition of enzymatic activity. The mechanism of inhibition is explained by a disturbance of the structure of the double helical DNA due to the interaction of the bound acridine derivates.

Studies on DNA repair in Bacillus subtilis. III. Identification of an exonuclease which enhances the priming activity of gamma-irradiated dna by "cleaning' damaged ends

An enzyme which enhances the priming activity of gamma-irradiated DNA for type I DNA polymerase (EC 2.7.7.7) was identified and partially purified from extracts of Bacillus subtilis cells. The enzyme preferentially degraded gamma-irradiated DNA into acid-soluble materials. DNA preparations treated with heat, ultraviolet light, pancreatic DNAase (EC 3.1.4.5) or micrococcal DNAase (EC 3.1.4.7) were not susceptible to the enzyme. However, sonication rendered DNA susceptible to the enzyme to some extent. From these results, it is supposed that this enzyme may function by 'cleaning' damaged terminals produced by gamma-irradiation to serve as effective priming sites for repair synthesis by the type I DNA polymerase.

Endonuclease activities in extracts of Micrococcus luteus that act on gemma-irradiated DNA

Several protein fractions containing endonuclease activity against gemma-irradiated DNA (gamma-endonuclease) were isolated from M. luteus. The crude extract was eluted on a phosphocellulose column and chromatographed on TEAE cellulose and subsequently on hydroxyapatite. Five peaks of gamma-endonuclease were obtained from each preparation. Repeated experiments showed comparable chromatographic behavior of the fractions. There was no detectable activity of U.V.-endonuclease in the fractions with gamma-endonuclease but a small contamination of endonuclease against unirradiated DNA and against DNA with apurinic sites. The gamma-endonuclease is stimulated by, but is not dependent on, magnesium. Several tests for endonuclease activity have been used: the analysis of strand breaks in calf-thymus DNA or in PM2 DNA, and the determination of end-groups formed by endonuclease, either 3'OH end-groups or phosphomonoester end groups. From the results obtained it can be assumed that the strand breaks induced by the gamma-endonuclease carry 3'OH and 5' phosphate end groups.

In vitro repair of radiation-induced strand breaks in DNA

DNA, gamma-irradiated in vitro or in isolated thymocytes was treated with several enzymes to achieve repair of the radiation-induced single strand braks. Whereas an incubation with polynucleotide ligase can join only 25% of the single strand breaks, a combined treatemnt with exonuclease III (EC 3.1.4.1), DNA polymerase I (EC 2.7.7.7), and polynucleotide ligase leads to repair of 80% of the breaks. For this in vitro repair the exonuclease III has to remove several, probably damaged, nucleotides from the 3'-terminal producing a single-stranded gap, which will be filled in by DNA polymerase I and joined by ligase. Tests for successful rejoining of the strand breaks were performed by showing the loss of primer 3'-OH sites for DNA polymerase I, by the resistance of incorporated nucleotides in the gap to removal by a second exonuclease III treatment, and by strand break determination in the analytical ultracentrifuge. 20% of the radiation-induced strand breaks will not be repaired by this combined treatment possibly due to an incomplete binding of the ligase on the 5'-terminals and/or an incomplete removal of the damaged 3'-terminals by exonuclease III.

Analysis of the breaking sites in the physical degradation of DNA

The 3'-termini of procaryotic and eucaryotic DNA fragments obtained by shearing, sonication and irradiation have been analyzed. Analysis of the 3'-ends of DNA fragments was done by 32-P-labeling with terminal transferase, hydrolysis of products by spleen DNAase and spleen exonuclease and separation of labeled 3'-terminal nucleotides on polyethyleneimine plates. In the case of sonication the deviation from DNA base composition of 3'-terminal nucleotides is very close to random for Escherichia coli and Haemophilius influenzae DNA, whereas for calf thymus, mouse and yeast mitochondrial DNAs a significant increase in dA and decrease in dC was observed. Shearing at high salt released random 3'-termini in E. coli DNA and 3'-termini with 4 to 6% deviation from base composition in calf thymus DNA. In the case of gamma-irradiation no real differences have been found between E. coli and calf thymus DNA and 3'-terminal nucleotide composition is very close to random. Mechanical breakage of eucaryotic DNA seems to release 3'-termini having a composition which differs slightly but significantly from the average base composition of the DNA.

Studies on DNA repair in Bacillus subtilis. I. A cellular factor acting on gamma-irradiated DNA and promoting its priming activity for DNA polymerase I

Initiation of new DNA synthesis was observed in B. subtilis cells upon gamma-ray irradiation followed by toluene treatment and incubation in the presence of the four deoxynucleotide triphosphates and Mg2+. This DNA synthesis took place in the absence of ATP and was refractory to 6-(p-hydroxyphenylazo)-uracil which is a specific inhibitor for the type III polymerase of Bacillus subtilis. This repair-type DNA synthesis was greatly reduced in mutant cells deficient in DNA polymerase I. Restoration of transforming activity of cellular DNA was found to occur in parellel with the above repair type DNA synthesis. A protein factor which enhances the priming activity of gamma-irradiated DNA for DNA polymerase I was detected in DNA-free extracts prepared from B. subtilis cells by means of lysis with a buffer containing lysozyme, Brij-58 and EDTA.

Studies on DNA repair in Bacillus subtilis. II. Partial purification and mode of action of an enzyme enhancing the priming activity of gamma-irradiated DNA

A cellular factor which makes T7 DNA irradiated with gamma-rays a better primer for Micrococcus DNA polymerase was partially purified by DEAE and phosphocellulose column chromatography and named "primer activating enzyme". Sucrose density gradient sedimentation analysis was carried out to examine actions of one major active fraction that appeared by phosphocellulose chromatography. It was shown that this factor introduced new nicks in T7 DNA in addition to those introduced directly by gamma-ray irradiation. This enzyme fraction also had an endonucleolytic activity towards DNA containing apurinic sites induced by heat treatment and had capacity to enhance the priming activity of heat- or methyl methansulfonate-treated DNA but affected very little that of ultraviolet-irradiated DNA. This enzyme had no effect on T7 DNA when it was not treated with the DNA-damaging agents. From these results we concluded that this enzyme may be analogous to the endonuclease II or apurinic site-specific enconuclease of Escherichia coli.

Oxygen--effect on strand breaks and specific end-groups in DNA of irradiated thymocytes

Thymocytes were irradiated with fast electrons up to 6 Mrad in the presence and absence of oxygen. The cells were treated before irradiation with a cold shock to prevent any repair rejection during irradiation. The DNA isolated subsequently was analysed for double-strand breaks (dsb), actual single-strand breaks (ssb) and alkali-induced strand breaks (alisb). We observed a linear increase of all types of lesions with dose and an o.e.r. for dsb of 3-6, for ssb of 4-9 and for alisb of 2-1. The data do not deviate significantly from those, measured on thymocytes irradiated without cold shock. In DNA of irradiated thymocytes, the frequency of 3' and 5' hydroxyl and 5' phosphate end-groups was analysed enzymatically. In both the ssb and alisb, about 11 per cent of the terminals carry 5'OH end-groups and 20-40 per cent 5' phosphate groups. On the 3' terminals, 60-80 per cent of the ssb are identified as 3'OH end-groups, whereas on the alisb only a small amount of 3'OH end-groups if found. The frequency of characterized end-groups shows the same oxygen effect as the corresponding strand breaks. Therefore, in the presence and absence of oxygen, the same mechanism may be responsible for formation of DNA strand breaks in vivo.

Time scale for rejoining of bacteriophage lambda deoxyribonucleic acid molecules in superinfected pol+ and polA1 strains of Escherichia coli after exposure to 4 MeV electrons

The time scale for rejoining of radiation-induced deoxyribonucleic acid (DNA) single-strand breaks was measured in the presence and absence of oxygen. The involvement of DNA polymerase I in this repair process was studied. Formation and rejoining of DNA strand breaks were measured in lambda DNA infecting lysogenic pol(+) and polA1 strains of Escherichia coli irradiated by 4 MeV electrons under identical conditions. Irradiation and transfer to alkaline detergent could be completed in less than 180 ms. The initial yields of DNA strand breaks were identical in pol(+) and polA1 host cells and four- to fivefold higher in the presence of oxygen than in nitrogen anoxia. Evidence for the existence of a very fast repair process, independent of DNA polymerase I, was not found, since no rejoining of radiation-induced DNA strand breaks was observed during incubation from 45 ms to 3 s. In pol(+) host cells most of the strand breaks produced in the presence of oxygen were rejoined within the first 30 to 40 s of incubation, whereas no rejoining could be detected within the same period of time in anoxic cells. Since no rejoining of broken lambda DNA molecules was observed in polA1 host cells, it is concluded that the synthetase activity of DNA polymerase I is involved in the rejoining of DNA breaks induced by radiation in the presence of oxygen.