Absence of swiveling at sites of intercalator-induced protein-associated deoxyribonucleic acid strand breaks in mammalian cell nucleoids

The sedimentation of DNA-nuclear protein complexes in 1.9 M salt-neutral sucrose gradients (nucleoid sedimentation) was used to examine the effects of the DNA intercalator 4'-(9-acridinylamino)methanesulfon-m-anisidide (m-AMSA) on mouse leukemia cell DNA. Mild detergent cell lysis and neutral pH make nucleoid sedimentation an extremely gentle, but sensitive, method to detect DNA scission. DNA breaks reduce the compaction of nucleoids and slow their sedimentation. Nucleoids from m-AMSA-treated cells sedimented as did those from untreated cells, indicating no detectable m-AMSA-dependent alterations in compaction despite an apparent underlying DNA break frequency of approximately 3 per 10(6) nucleotides, as measured by alkaline elution with proteinase. Mild proteinase digestion of cell lysates prior to nucleoid sedimentation unmasked some, but not all, of the underlying breaks. The frequency of DNA-protein cross-links in nucleoids from cells treated with m-AMSA was comparable to the single-strand break frequency produced by m-AMSA in whole cells. These results indicate that m-AMSA-induced DNA-protein cross-links conceal DNA breaks so as to prevent swiveling around the breaks within the nucleoids. This unique sort of DNA scission is consistent with the involvement of topoisomerases in the DNA breaks elicited by intercalators in mammalian cells.     

Characterization of intracellular DNA strand breaks induced by neocarzinostatin in Escherichia coli cells.

DNA strand breaks induced by Neocarzinostatin in Escherichia coli cells have been characterized. Radioactively labeled phage lambda DNA was introduced into lysogenic host bacteria allowing the phage DNA to circularize into superhelical molecules. After drug treatment DNA single- and double-strand breaks were measured independently after neutral sucrose gradient sedimentation. The presence of alkali-labile lesions was measured in parallel in alkaline sucrose gradients. The cell envelope provided an efficient protection towards the drug, since no strand breaks were detected unless the cells were made permeable with toluene or with hypotonic Tris buffer. In permeable cells, no double strand breaks could be detected, even at high NCS concentration (100 micrograms/ml). Induction of single-strand breaks leveled off after 15 min at 20 degrees C in the presence of 2 mM mercaptoethanol. Exposure to 0.3N NaOH doubled the number of strand breaks. No enzymatic repair of the breaks could be observed.     

Alkali lability and rapid initiation of excision repair following photoaffinity damage by ethidium azide

DNA damage and repair provoked by ethidium azide (EA) photoaffinity labeling in mouse leukemia cells was studied by measuring sedimentation properties of nucleoids in neutral sucrose gradients, and it was found that the strand opening step was faster than that which followed damage of cells by ultraviolet (UV) light. The two insults were compared at levels of damage which gave the same overall rates of repair synthesis in intact cells and which required the same length of time to complete repair, as judged by the restoration of supercoiling of the isolated nucleoids. In the case of UV, single-strand breaks in DNA were detectable at 30 min, maximum at 2 h, and the superhelical properties restored at 21 h. With photoaffinity labeling, single-strand breaks were prominent immediately, even when photolabeling of cells was done on ice, but restoration of DNA supercoiling still required 21 h. Photolabeling of isolated nucleoids or isolated viral DNA with EA failed to introduce DNA strand breaks. However, it was discovered that photoaffinity labeling of DNA with EA resulted in alkali labile sites shown by single strand breaks produced on alkaline sucrose sedimentation or by alkali exposure followed by sedimentation on neutral formamide gradients. These results suggest that the drug attachment sites should be identifiable by the location of such single strand breaks.     

Induction of proteinase K-sensitive sites and M. luteus endonuclease-sensitive sites in DNA of barley embryos by sodium azide

DNA damage induced in germinating barley embryos by mutagenic and sublethal doses (0.1–2 mM, 2 h) of sodium azide, applied at pH 3, was measured by alkaline elution. Isolated nuclei were lysed at a high pH with either 2% SDS or 2 M NaCl on polyvinyl chloride filters and digested with proteinase K or with Micrococcus luteus endonuclease prior to elution. The azide treatments resulted in a dose-dependent increase of proteinase K-sensitive sites and an appearance of Micrococcus luteus endonuclease-sensitive sites. These sites were detected as DNA single-strand breaks after digestion of the DNA with either one or both of the enzymes. The two types of lesion were additive and occurred in a ratio of about 1:1. The additive effect suggested independent origin for the two types of lesion. Breaks independent of proteinase K digestion appeared only when DNA was analysed 24 h after the action of azide. The nature and significance of these DNA lesions are discussed.     

Growth-medium-dependent repair of DNA single-strand and double-strand breaks in X-irradiated Escherichia coli

The X-ray resistance of logarithmic phase cells of Escherichia coli K-12 is enhanced threefold by growth in rich medium versus minimal medium (N. J. Sargentini, W. P. Diver, and K. C. Smith, Radiat. Res. 93, 364-380, 1983). In this work, X-ray-induced DNA strand breaks were assayed by sedimentation in alkaline and neutral sucrose gradients to correlate the enhanced survival of rich-medium-grown cells with an enhanced capacity for DNA repair. While rich-medium-grown cells showed no enhanced capacity for repairing DNA single-strand breaks in buffer, i.e., fast, polA-dependent repair, they did show an enhanced capacity to repair both single-strand and double-strand breaks in growth medium, i.e., slow, recA-dependent repair. This enhanced capacity for DNA repair in rich-medium-grown cells was inhibited by rifampicin post-treatment, indicating the requirement for de novo RNA synthesis. Kinetic studies indicated that the repair of DNA double-strand breaks was a complex process. Relative to the sedimentation rate in neutral sucrose gradients of nonirradiated DNA, the sedimentation rate of X-irradiated DNA first changed from slow to very fast. Based on alkaline sucrose gradient sedimentation studies, all the strand breaks had been repaired during the formation of the very fast sedimenting DNA. With continued incubation, the sedimentation rate of the DNA on neutral sucrose gradients decreased to the normal rate.     

Repair of Alkylation Damage: Stability of Methyl Groups in Bacillus subtilis Treated with Methyl Methanesulfonate

Bacillus subtilis was not inactivated and was able to replicate even though approximately 3 x 10(4) methyl groups added by methyl methanesulfonate (MMS) were bound to the deoxyribonucleic acid (DNA) of each organism. No significant loss of methyl groups from the DNA occurred for several generations upon incubation of methylated wild-type or MMS-sensitive cells. Single-strand breaks were not observed in the DNA from cells treated at this low MMS dose. Higher doses of MMS resulted in significant killing of both wild-type and MMS-sensitive strains, and the DNA extracted from such treated cells sedimented more slowly than control DNA through alkaline sucrose gradients, indicating the presence of breaks or apurinic sites (or both). These breaks were repaired upon incubation of wild-type but not of MMS-sensitive strains. Repair of damage induced by alkylating agents is probably the repair of breaks which occur as a consequence of high levels of alkylation.     

Toxicity and DNA damage induced by 1-nitropyrene and its derivatives in Chinese hamster lung fibroblasts

1-Nitropyrene and its chemically synthesised derivatives were investigated for their cytotoxicity and ability to induce DNA-strand breaks in Chinese hamster lung fibroblasts. Both 1-nitrosopyrene (0.25-60 micrograms/ml) and 1-aminopyrene (0.25-25 micrograms/ml) were cytotoxic, and induced the formation of DNA lesions, which were measured as DNA single-strand breaks after sedimentation in alkaline sucrose-density gradients. Higher doses of 1-aminopyrene (25-60 micrograms/ml) inhibited the formation of DNA single-strand breaks. 1-Nitropyrene was not toxic (0.25-60 micrograms/ml) and induced low levels of detectable DNA strand breaks, whilst N-acetyl-1-aminopyrene was inactive. The post-mitochondrial supernatant fraction of Aroclor-induced rat-liver containing 4 mM NADPH (S9 mix) did not promote the activation of 1-nitropyrene. In fact DNA strand breaks induced by either 1-nitropyrene or 1-nitrosopyrene was abolished in the presence of S9 mix. The 1-nitropyrene reduced intermediate, N-hydroxy-1-aminopyrene was synthesised by the reduction of 1-nitrosopyrene with ascorbic acid. In the presence of ascorbic acid, 1-nitrosopyrene caused a 5-fold increase in the number of DNA single-strand breaks when compared to cells treated with 1-nitrosopyrene alone. The results are discussed in terms of the metabolic activation of 1-nitropyrene and 1-aminopyrene in Chinese hamster lung cells.     

Azaserine: further evidence for DNA damage in Escherichia coli

Azaserine causes DNA damage in stationary-phase cells. In our investigation of this damage, we used strains of Escherichia coli differing in repair capabilities to study azaserine-induced DNA damage, detected as DNA strand breaks by sucrose gradient sedimentation techniques. Reduced sedimentation in alkaline and neutral sucrose gradients indicated the presence of both alkali-labile sites and in situ strand breaks. Azaserine induced DNA single-strand breaks (SSBs) abundantly in all but the recA strain, in which SSBs were greatly reduced. Treatment of purified DNA with azaserine from bacteriophages T4 and PM2 produced no detectable SSBs. Several other studies also failed to detect DNA damage induced directly by azaserine. Increased levels of beta-galactosidase were induced in an E. coli strain possessing a rec::lac fusion, providing further evidence for azaserine induction of the recA gene product. In addition, azaserine induced adaptation against killing but not against mutagenesis in wild-type E. coli strain.     

Induction by an hepatic carcinogen, 1-nitroso-5,6-dihydrouracil, of single and double strand breaks of liver DNA with rapid repair

The nitrosoureas derived from 3 naturally occurring ureides were administered to rats and the velocity sedimentation of hepatic DNA in alkaline and neutral sucrose gradients determined. The potent hepatocarcinogen 1-nitroso-5,6-dihydrouracil induced apparent double strand as well as single strand breaks in liver DNA within 30 minutes. This damage seemed to be repaired within 4 hours. In contrast, 1-nitrosohydantoin and δ-nitroso-L-citrulline, neither of which are known hepatocarcinogens, did not modify the velocity sedimentation of hepatic DNA.     

Chemical radiosensitization by misonidazole: production and repair of DNA single-strand breaks in Yoshida ascites tumor cells.

Formation of strand-breaks in DNA and its repair in Yoshida ascites tumor cells exposed to gamma radiation (100-400 Gy) in presence and absence of misonidazole (10 mM) were studied. The methodology involved pre-labelling of cellular DNA by 3H-thymidine during cell proliferation in rats, irradiation of cells in vitro and analysing sedimentation profile of DNA by ultracentrifugation in alkaline sucrose density gradients. Irradiation under euoxic conditions resulted in formation of about 1.5 times greater number of strand breaks as compared to those formed during irradiation under hypoxic conditions. Misonidazole (10 mM) by its presence along with the cells during irradiation under hypoxic conditions caused a 3-fold increase in the number of single strand breaks, but under euoxic conditions of irradiation the presence of misonidazole did not enhance the strand break formation. Incubation of cells irradiated in absence of misonidazole for 1 hr in tissue culture medium at 37 degrees C resulted in repair of substantial fraction of the strand breaks while there was no repair of the DNA strand breaks in cells irradiated in the presence of the chemical.     

Gamma radiation-induced single strand breaks in DNA and their repair in spheroplasts and nuclei of light-grown and dark-grown Euglena cells

Exposure of light-grown and dark-grown Euglena cells to gamma radiation causes single strand breaks in nuclear DNA as assessed by sedimentation analysis in alkaline sucrose density gradients. The number of radiation-induced single strand breaks in nuclear DNA of light-grown cells is found to be less than that in dark-grown cells. Post-irradiation incubation of both types of cells in 0 . 1 M phosphate buffer, pH 7 . 0 at 25 degrees C for 1 hour results in restitution of the strand breaks in DNA. Light-grown cells (cells with chloroplasts) are able to rejoin all the single strand breaks in DNA produced by gamma irradiation at D50 and D5 doses. On the other hand, dark-grown cells (cells devoid of chloroplasts) are unable to rejoin all the strand breaks caused by irradiation at either of the doses. The rate of DNA repair in dark-grown cells is also much slower than that in light-grown cells. Radiation-induced single strand breaks in DNA and their repair in nuclei from both types of cells is found to be similar to that observed in the spheroplasts. It is suggested that some factor(s) elaborated by chloroplasts may contribute towards the efficiency of nuclear DNA repair in Euglena cells.     

Sedimentation Analysis of DNA from Irradiated and Unirradiated L Cells

DNA, released from unirradiated mouse L-cells gently lysed in a thin layer of 2% sucrose on top of an alkaline sucrose gradient, was found to sediment in a narrow band with a sedimentation coefficient of about 500S. Exposure of cells to increasing doses of X-rays (89-712 rads) continuously reduced the DNA sedimentation velocity until, after about 890 rads, the DNA appeared in a narrow peak with a sedimentation coefficient of approximately 180S. As the dose given to cells was increased beyond 890 rads, the sedimentation coefficient of the DNA released continued to decrease and the sedimentation profiles now broadened in a manner consistent with the random production of single-strand breaks in the DNA. The DNA released from unirradiated cells (500S) is thought to be loosely aggregated and only partially single stranded. It is presumed that cells exposed to low doses of radiation release DNA with marked reductions in sedimentation coefficient because single-strand breaks produced in the DNA aid the alkaline denaturation process. By using the system to be described, it has been possible to demonstrate DNA repair (rejoining of X-ray-induced single-strand breaks) during postirradiation incubation of cells given doses as low as 400 rads.     

Biochemical analysis of damage induced in yeast by formaldehyde. I. Induction of single-strand breaks in DNA and their repair.

Analysis of sedimentation profiles in alkaline sucrose gradients showed that, through a metabolic process, formaldehyde (FA) produced single-strand breaks in DNA of exponential phase cells of haploid wild-type Saccharomyces cerevisiae. The production of this type of lesion was dose-dependent. Strains defective in excision-repair of pyrimidine dimers induced by ultraviolet (UV) irradiation showed a reduced capacity to undergo single-stand breaks after treatment with FA. This indicates that the repair pathways of damage induced by UV and FA share a common step. Post-treatment incubation of wild-type cells in growth medium indicate a lag in cell division during which a slow recovery of DNA with a normal size was observed.     

Single-strand breakage in DNA of Escherichia coli exposed to Cd2+.

When a growing culture of Escherichia coli was exposed to 3 X 10(-6) M Cd2+, 85 to 95% of the cells lost their ability to form colonies on agar plates. Loss of viability was accompanied by considerable single-strand breakage in the DNA, with no detectable increase in double-strand breaks. A direct correlation appeared to exist between the number of single-strand breaks and the concentrations of Cd2+ to which the cells were exposed. Exposure of DNA in vitro to a Cd2+ concentration of 3 X 10(-6) M or higher, followed by sedimentation in alkaline sucrose gradients, demonstrated no single-strand breaks. Cadmium-exposed cells recovered viability when incubated in Cd2+-free liquid medium containing 10 mM hydroxyurea. During the early period of recovery, there was a lag in the incorporation of labeled thymidine, but cellular DNA, at least in part, appeared to be repaired.     

Differentiation of apurinic/apyrimidinic sites and single-strand breaks in DNA by formamide- and alkaline-sucrose gradient sedimentation

The excision repair of DNA damaged by physical or chemical agents may produce either apurinic/apyrimidinic (AP) sites or single-strand breaks (SSB) in the DNA. Alkaline-sucrose gradient sedimentation and alkaline elution, techniques generally used for the study of DNA repair which depend upon high pH to denature the DNA, cannot differentiate between these possibilities. A simple method for the quantitative measurement of SSB in DNA which leaves any AP sites intact is presented. This method relies upon the separation by size of the fragments resulting from the denaturation of the DNA under neutral conditions by sedimentation through gradients of sucrose in formamide. By combining the use of both formamide- and alkaline-sucrose sedimentation methods, we can quantify both AP sites and SSB in DNA.     

Removal of pyrimidine dimers from Saccharomyces cerevisiae nuclear DNA under nongrowth conditions as detected by a sensitive, enzymatic assay.

A sensitive and quantitative procedure for the detection of pyrimidine dimers in yesast nuclear DNA is described. The assay employs dimer-specific, endonuclease activities from Micrococcus luteus together with DNA sedimentation through calibrated, alkaline sucrose gradients to detect endonuclease-induced, single-strand breaks. Breaks were induced in a dose-dependent manner from 0 to 80 J m-2 at 254 nm and in numbers equivalent to the numbers of dimers induced by similar doses (Unrau et al., Biochim. Biophys. Acta, 312 (1973) 626--632). This procedure also allows the use of [6-3H] uridine to label cellular nucleic acids, but dose not require extensive DNA purification to eliminate concomitantly labeled RNA. Endonuclease-sensitive sites in the wild-type, haploid strain S288C, after irradiation with 5 J m-2 (254 nm), were removed in less than 5 min when cells were incubated in buffer (pH 7.0) at 28 degrees C. After irradiation with doses from 30 to 100 Jm-2 site removal in S288C required longer postirradiation incubations and was about 90% complete. In a radiation-sensitive strain carrying the mutant allele rad4-3 the number of endonuclease-sensitive sites remained constant for 6 h after irradiation with 5 Jm-2. The retention of sites in this strain indicates that it is defective in the excision of pyrimidine dimers.     

Mode of inhibition of DNA replication in neocarzinostatin-treated HeLa cells

The effect of antitumor antibiotic neocarzinostatin on DNA replication in HeLa cells was studied by pulse-labeling of DNA with [3H]thymidine and sedimentation analysis of the DNA with alkaline sucrose gradients. The drug, which produced DNA damage, primarily inhibited the replicon initiation in the cells at low doses (less than or equal to 0.1 microgram/ml), and at high doses (greater than or equal to 0.5 microgram/ml) inhibited the DNA chain elongation. An analysis of the number of single-strand breaks of parental DNA, induced by neocarzinostatin, indicated that inhibition of the initiation occurred with introduction of single-strand breaks of less than 1.5 . 10(4)/cell, while inhibition of the elongation occurred with introduction of single-strand breaks of more than 7.5 . 10(4)/cell. Assuming that the relative molecular mass of DNA/HeLa cell was about 10(13) Da, the target size of DNA for inhibition of replicon initiation was calculated to be about 10(9) Da, such being close to an average size of loop DNA in the cell and for inhibition of chain elongation, 1-2 . 10(8) Da which was of the same order of magnitude as the size of replicons. Recovery of inhibited DNA replication by neocarzinostatin occurred during post-incubation of the cells and seemed to correlate with the degree of rejoining of the single-strand breaks of parental DNA. Caffeine and theophylline enhanced the recovery of the inhibited replicon initiation, but did not aid in the repair of the breaks in parental DNA.     

The effect of thymine starvation on chromosomal structure of Escherichia coli JG-151

Labelled DNA extracted from control and thymine starved cells was qualitatively characterized with respect to sedimentation properties in alkaline sucrose gradients. DNA isolated from cells undergoing loss of division ability demonstrated decreasing sedimentation velocity. Sedimentation profiles of DNA extracted from cells which were starved for thymine under conditions which allowed spontaneous recovery of division ability to occur, demonstrated an increase in DNA sedimentation velocity toward normal control value. It appears that while thymine starvation can result in single strand breaks, this damage is not irreversible, for under certain conditions rejoining of the breaks can occur.     

In vivo repair of rat liver DNA damaged by dimethylnitrosamine or diethylnitrosamine.

Effects of hepatocarcinogens dimethylnitrosamine (DMN) and diethylnitrosamine (DEN) on the sedimentation pattern of rat liver DNA in alkaline sucrose gradients were studied with regard to time and dose dependency. Both DMN (10 mg/kg body weight) and den (13.4 or 134 mg/kg) induced appreciably decreased DNA sedimentation rates at 24 h after injection. DMN at 10 mg/kg was as effective in decreasing the DNA sedimentation rate at 24 h after injection as was the higher dose of DEN (134 mg/kg). Sedimentation patterns at 1, 6 and 14 days after injection indicated that damage induced by DEN (134 mg/kg) was repaired at a substantially lower rate than DMN (10 mg/kg) induced damage. When effects of equimolar doses of DMN (10 mg/kg) and DEN (13.4 mg/kg) were compared at 1, 6 and 14 days after injection, it was observed that the more pronounced damage of rat liver DNA induced by DMN was repaired at a faster rate than was the DEN-induced damage. At the molecular level this difference in repair between damage induced by the two nitrosamines is probably related to different DNA alkylation patterns. The relatively persistent nitrosamine-induced DNA lesions (observed especially after DEN administration) are thought to represent phosphotriesters which give rise to single strand DNA breaks at strongly alkaline conditions of lysis on top of the gradient. The results are discussed in relation to the possible significance of alkylation and repair of DNA in the formation of (pre)cancerous lesions in rat liver.     

Repair of neocarzinostatin-induced deoxyribonucleic acid damage in human lymphoblastoid cells: possible involvement of apurinic/apyrimidinic sites as intermediates

Neocarzinostatin (NCS) induces repair in a xeroderma pigmentosum lymphoblastoid line deficient in the ability to repair DNA damage induced with (acetoxyacetyl-amino)fluorene. Repair was demonstrated by the induction of repair synthesis and by the disappearance of NCS-induced single-strand breaks and/or alkaline-labile sites in DNA. Estimation of NCS-induced repair patch size, based on the density shift induced in DNA by extensive shear after incubation of treated cells in medium with bromodeoxyuridine or by calculation from the extent of restoration of DNA sedimentation profiles in alkaline sucrose gradients and the amount of repair synthesis measured by the BND cellulose method, indicated that only a few nucleotides were inserted per repaired region. NCS-treated bacteriophage T7 DNA requires incubation with alkaline phosphatase to make it a substrate for DNA polymerase I. NCS-reacted T7 DNA, even after phosphatase treatment, is not a substrate for a DNA polymerase alpha obtained from human lymphoma cells. NCS-treated T7 DNA did serve as a substrate for the DNA polymerase alpha when incubated with an apurinic/apyrimidinic (AP) endonuclease with associated 5'-3'-exonuclease activity. The results suggest that NCS-induced AP sites could be intermediates for the in vivo repair synthesis.