Damage to DNA and activity of nuclear DNA repair and replicative enzymes following N-nitrosodiethylamine treatment to rats

Continuous administration in the drinking water of hepatocarcinogen N-nitrosodiethylamine (NDEA) to male rats (200 mg/L) for 60 days resulted in DNA damage in the form of single strand breaks. The damage, which is measured as a shift in the sedimentation of DNA in alkaline sucrose density gradients, was found to be maximum at the fourth week of treatment, and the sedimentation pattern of DNA was found to return to near normal size by the seventh week of NDEA treatment. Simultaneously, there were perturbations in the nuclear enzymes involved in DNA replication and repair. Activities of DNA polymerase beta, DNA ligase, and topoisomerase were found to increase in as early as the first week of NDEA treatment and reached the maximum at the fourth week, and thereafter declined to normal level by the eighth week of treatment. Concomitantly, the activities of DNA polymerase alpha, DNA primase, and RNA polymerase which were unaltered in the initial period of carcinogen treatment recorded a marked increase after sixth week of NDEA treatment. Results suggest that administration of NDEA inflicts DNA damage, which is manifested as increase in DNA repair enzymes in the initial period and activated DNA replicative enzymes at a later period, indicating the active proliferation of transformed cells.     

DNA replication in human cells treated with methyl methanesulfonate

Methyl methanesulfonate (MMS) affects the production of DNA in human cells by reducing the rate of DNA synthesis and by causing the DNA to be synthesized in smaller than normal segments. DNA profiles from alkaline sucrose gradients from cells treated with MMS for 1 h and pulse-labeled at 2.5 h after treatment show more slow-sedimenting DNA than profiles from untreated cells or treated cells pulsed at 0.5 or 4 h after the 1-h treatment. Upon incubation of the pulse-labeled DNA there is an increase in the amount of fast-sedimenting DNA in each sample, indicating repair of the lesions.The amount of DNA synthesized is also reduced 2.5 h after a 1-h treatment but is at near normal levels at 0.5 and 4 h. The reduction in the size of the DNA segments synthesized and the reduction in the rate of DNA synthesis probably reflect the formation and repair of lesions in the parental DNA.     

Transfection of Escherichia coli Spheroplasts IV. Transfection of rec+ and rec? Spheroplasts by Native,Denatured, and Renatured T5 Bacteriophage DNA After Repair of Single-Strand Breaks by Polynucleotide Ligase

Transfection of Escherichia coli spheroplasts by native T5 phage DNA was not affected by treatment with polynucleotide ligase. Denatured T5 phage DNA infectivity, only 0.1% of the native DNA level, was increased slightly by polynucleotide ligase treatment. Renatured T5 phage DNA infectivity was also increased slightly by polynucleotide ligase treatment. To form an infective center with rec(+) spheroplasts, 1.6 to 2.1 native T5 phage DNA molecules were required; however, 1.4 T5 phage DNA molecules were required to form an infective center with recA(-)B(-) spheroplasts, and one molecule was sometimes sufficient for rec B(-) spheroplasts. Polynucleotide ligase treatment of T5 phage DNA had no effect on these parameters. Thus, the single-strand interruptions of T5 phage DNA are probably not essential to the survival of the parental T5 phage DNA, and T5 phage DNA, especially the denatured form, is highly sensitive to some nucleases in E. coli spheroplasts.     

Differences between survival, mutagenicity and DNA replication in MMS- and MNU-treated V79 hamster cells

After treatment with methyl methanesulfonate (MMS) or N-methyl-N-nitrosourea (MNU), the mutagenicity and survival of Chinese hamster V79 cells were investigated, as well as the inhibition of daughter DNA synthesis and, using the DNA unwinding technique and hydroxylapatite chromatography, the character of the newly synthesized DNA was studied. It was found that different cytotoxicity and mutagenicity of MMS and MNU was accompanied by different types of DNA synthesis inhibition. The treatment with the former compound resulted in a longer inhibition of DNA synthesis, while the treatment with the latter showed that as early as 2 h after exposure the percentage of nascent DNA increased. Shortly after the exposure to both alkylating agents, the newly synthesized DNA contained a higher number of gaps than control DNA, in dependence on the concentration used. During culturing after treatment, the character of nascent DNA in MMS-treated cells gradually returned to that of control DNA, while MNU-treated cells, for the whole time of our study, synthesized DNA with a larger number of gaps than control DNA. We suggest that the character of nascent daughter DNA reflects the occurrence of lesions in parental DNA. These are repaired within a shorter time in MMS- than in MNU-treated cells. The long-term persistence of lesions in the DNA of MNU-treated cells might be one of the factors responsible not only for the higher cytotoxic but also for the many times higher mutagenic effect of this alkylating agent.     

Inhibition by hyperthermia of repair synthesis and chromatin reassembly of ultraviolet-induced damage to DNA

We have investigated the effects of hyperthermia treatment on sequential steps of the repair of UV-induced DNA damage in HeLa cells. DNA repair synthesis was inhibited by 40% after 15 min of hyperthermia treatment at 45 degrees C; greater inhibition of repair synthesis occurred with prolonged incubation at 45 degrees C. Enzymatic digestion of repair-labeled DNA with Exonuclease III indicated that once DNA repair was initiated, the DNA repair patch was synthesized to completion and that ligation of the DNA repair patch occurred. Thus the observed inhibition of UV-induced DNA repair synthesis by hyperthermia treatment may be the result of inhibition of enzymes involved in the initiating step(s) of DNA repair. DNA repair patches synthesized in UV-irradiated cells labeled at 37 degrees C with [3H]Thd were 2.2-fold more sensitive to micrococcal nuclease digestion than was parental DNA; if the length of the labeling period was prolonged, the nuclease sensitivity of the repair patch synthesized approached that of the parental DNA. DNA repair patches synthesized at 45 degrees C, however, remained sensitive to micrococcal nuclease digestion even after long labeling periods, indicating that heat treatment inhibits the reassembly of the DNA repair patch into nucleosomal structures.     

Reaction of dihydropyrrolizines with deoxyribonucleic acids in vitro

1. Thermal denaturation profiles of Escherichia coli DNA pretreated with monocrotaline pyrrole in vitro showed no difference from control DNA samples during heating. A substantial increase in the degree of renaturation during cooling of the pretreated DNA samples was observed. The degree of renaturation was dependent on the concentration of pyrrole used. 2. When rat liver DNA was pretreated with monocrotaline pyrrole there was a greater degree of renaturation after heat treatment than was found with E. coli DNA. 3. Equilibrium-density-gradient centrifugation in alkaline caesium chloride showed that DNA pretreated with monocrotaline pyrrole and heat denatured, renatured to a greater extent on quenching in ice than did untreated control DNA. The degree of renaturation was similar whether the initial treatment of the DNA with pyrrole was for 1 or for 15min. The reaction also appeared to be independent of pH between 5.5 and 9.0. 4. Retrorsine pyrrole was as effective as monocrotaline pyrrole in cross-linking the DNA, but monocrotaline pyrrole exposed to water for 5min before the addition of the DNA was ineffective. Pretreatment of E. coli DNA with synthetic bis-hydroxymethylpyrrole esters also caused renaturation after heat treatment. Monoesters were ineffective. 5. After treatment of rats with retrorsine, no cross-linking of the liver DNA could be demonstrated.     

An investigation of the mechanism of the reciprocal differential staining of BUdR-substituted and unsubstituted chromosome regions.

After treatment with hot NaH₂PO₄ at pH 9, BUdR-substituted and unsubstituted chromosome regions are palely and intensely stained with Giemsa, respectively; however, after treatment with the same solution at pH 4, the reciprocal staining patterns are produced, i.e. these chromosome regions are intensely and palely stained, respectively. The nature of the mechanisms responsible for this reciprocal differential Giemsa staining of BUdR-substituted and unsubstituted chromosome regions has been investigated by Feulgen staining, electron microscopy, and radioisotope analyses involving scintillation counting and autoradiography. The results indicate that different mechanisms are responsible for the two types of staining effect. The high pH NaH₂PO₄ treatment preferentially extracts BUdR-substituted DNA into the treatment solution, relative to unsubstituted DNA. The collective evidence from this and other work suggests that BUdR-substituted DNA in the chromosomes is partially photolysed by exposure to daylight during the harvesting procedure, and the degraded DNA is subsequently solubilized and extracted during the high pH treatment. This quantitative reduction of DNA in the BUdR-substituted chromosome regions results in pale Giemsa staining of these regions. The low pH NaH₂PO₄ treatment does not produce a significant extraction of either BUdR-substituted or unsubstituted DNA into the treatment solution; rather, there may be a redistribution of the unsubstituted DNA relative to the BUdR-substituted DNA such that the unsubstituted DNA is preferentially dispersed outside the boundaries of the chromosomes onto the surrounding area of the slide. It is suggested that the BUdR-substituted chromosome regions stain relatively intensely with Giemsa after the low pH treatment because the DNA in these regions is less dispersed than that in the unsubstituted regions.     

Phosphodiester bonds between polypeptides and chromosomal DNA

Polypeptides co-purifying with DNA in alkali are covalently bound to DNA. DNA purified by treatment with alkali, sodium dodecyl sulphate and phenol absorbed 125I under conditions designed to radioiodinate exclusively tyrosine and histidine in peptides. A significant amount of the absorbed 125I remained associated with DNA during treatment with phenol as well as during precipitation with ethanol from neutral and alkaline solutions. However, after prolonged digestion with proteinase K, most of the radiolabelled material could be removed from 125I-treated DNA. Further treatment with a second protease (Pronase) released no larger fraction of the 125I label. The residual radiolabelled material could be precipitated together with DNA by ethanol and it remained associated with DNA also in the presence of alkali (95 degrees C), acid (37 degrees C) and hydroxylamine (37 degrees C). In contrast, radiolabelled peptides were released from DNA by treatment with hot piperidine (10% at 95 degrees C) and by agents that hydrolyse peptides and modify DNA, e.g. strong acid (95 degrees C) and formic acid/diphenylamine. The radiolabelled peptides, once released from DNA by these chemical methods, could be further cleaved by Pronase. This shows that the residual DNA/peptide complex isolated after prolonged protease digestion is protease-resistant unless it is cleaved or otherwise modified by harsh chemical treatment. The linking groups between deoxynucleotides and the radiolabelled residual peptides could be isolated by digestion of DNA in the DNA/peptide complex. Radiolabelled peptides could be released from this linking group material by phosphodiesterases, indicating the involvement of phosphodiesters in the linking groups.     

The kinetics of DNA damage by bleomycin in mammalian cells.

The kinetics of DNA damage by bleomycin (BLM) was assessed by measuring the amount of DNA breakage induced by BLM at different doses, treatment lengths, and treatment temperatures. DNA degradation was measured with the alkaline unwinding method. Comparison of the curves of DNA cleavage by BLM leads to the conclusion that low doses (1-5 micrograms/ml) and short treatments (5-15 min) produce marked damage in the DNA. High increases in BLM concentration produce relatively small increases in DNA damage above the levels obtained with low doses. Extension of treatment times does not increase the DNA degradation above the rate observed with 15-min treatments. The repair of DNA damage starts at about 15 min after the initiation of treatment. The mending of DNA breaks is very fast and extensive when BLM is no longer present. Repair not only implies the closing of DNA nicks, but very likely the degradation of the BLM molecules intercalated in the DNA interrupting the reactions responsible for the generation of free radicals. Persistence of BLM in the cell environment facilitates the replacement of degraded BLM molecules by new ones. This produces the persistent production of free radicals and the establishment of a balance between the processes of DNA damage and repair.     

Characterization of hepatitis B virus DNA polymerase

Hepatitis B virus (HBV) particles were separated from the blood-plasma containing HBe and HBs antigens (subtype adr) and the nature of the endogenous DNA polymerase in the HBV core particles was studied. The HBV endogenous DNA polymerase activity was examined under the conditions used for preparation of HBV vaccine. The endogenous DNA polymerase activity was reduced slowly upon the heat treatment or the formalin treatment. The reductions of the activity were 65% and 70% upon the heat treatment at 60 C for 10 hr and the formalin treatment at 37 C for 90 hr, respectively. Properties of the HBV endogenous DNA polymerase were studied by utilizing specific inhibitors against the eukaryotic DNA polymerases. Our results showed that the HBV endogenous DNA polymerase is resistant to aphidicolin and N-ethylmaleimide, and sensitive to 2',3'-dideoxythymidine 5'-triphosphate, phosphonoformic acid and 9-beta-D-arabinofuranosyladenosine 5'-triphosphate.     

Control of carry-over contamination for PCR-based DNA methylation quantification using bisulfite treated DNA

In this study, we adapted the well known uracil DNA glycosylase (UNG) carry-over prevention system for PCR, and applied it to the analysis of DNA methylation based on sodium bisulfite conversion. As sodium bisulfite treatment converts unmethylated cytosine bases into uracil residues, bisulfite treated DNA is sensitive to UNG treatment. Therefore, UNG cannot be used for carry-over prevention of PCR using bisulfite treated template DNA, as not only contaminating products of previous PCR, but also the actual template will be degraded. We modified the bisulfite treatment procedure and generated DNA containing sulfonated uracil residues. Surprisingly, and in contrast to uracil, 6-sulfonyl uracil containing DNA (SafeBis DNA) is resistant to UNG. We showed that the new procedure removes up to 10 000 copies of contaminating PCR product in a closed PCR vessel without significant loss of analytical or clinical sensitivity of the DNA methylation analysis.     

The nature of inactivating lesions produced by platinum(II) complexes in phage lambda DNA

Lambda DNA loses transfectivity and acquires interstrand cross-links after treatment with either trans-Pt(II) or cis-Pt(II). With trans-Pt(II) there is close to an equivalence between the fraction of lambda DNA cross-linked and the fraction inactivated. In contrast, with cis-Pt(II) there are approx. 5 inactivating lesions for each lambda DNA interstrand cross-link. These results suggested that trans-PT(II) does not introduce intrastrand inactivating lesions into lambda DNA while cis-Pt(II) does so. To verify this conclusion, the cross-linked and uncross-linked fractions of lambda DNA treated with trans-PT(II) or cis-Pt(II) were separated on alkaline sucrose gradients. After trans-Pt(II) treatment, the uncross-linked fraction of lambda DNA was transfective when renaturated. However after cis-Pt(II) treatment the uncross-linked fraction of lambda DNA was not transfective when renatured. Thiourea treatment restored transfectivity to all inactivated fractions, showing that these lesions are reversible. We conclude that trans-Pt(II) inactivates lambda DNA primarily by introducing interstrand cross-links but that cis-Pt(II), although it also introduces interstrand cross-links, inactivates lambda DNA primarily by introducing intrastrand lesions.     

DNA plasmid production in different host strains of <Emphasis Type="Italic">Escherichia coli</Emphasis>

We compared plasmid DNA production in 13 strains of Escherichia coli in shake flasks using media containing glucose or glycerol. DNA yield from either carbon source showed small correlation with maximum growth rate. Three strains, SCS1-L, BL21 and MC4100, were selected for a controlled exponential fed-batch process at a growth rate of 0.14 h⁻¹ to an optical density of about 70, followed by a four-hour heat treatment. Prior to heat treatment, SCS1-L generated 15.4 mg DNA/g, BL21 generated 11.0 mg DNA/g and MC4100 generated 7.9 mg DNA/g, while after heat treatment the strains attained DNA yields, respectively, of 18.0, 15.0 and 6.8 mg/g. The strains also varied in their percentage of supercoiled DNA after heat treatment, with SCS1-L averaging 66% supercoiled, BL21 17% and MC4100 40%. We further investigated the two strains that yielded the highest percentage of supercoiled DNA (SCS1-L and MC4100) at a higher growth rate of 0.28 h⁻¹. At this condition, a slightly lower DNA yield was generated faster, and the percentage of supercoiled DNA increased. Heat treatment improved DNA yield, and surprisingly did so to a greater extent at the higher growth rate. As a consequence of these factors, higher growth rates might be advantageous for DNA production.     

DNA repair and replication in human fibroblasts treated with (+/-)-r-7,t-8-dihydroxy-t-9,10-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene

DNA repair and replication were examined in diploid human fibroblasts after treatment with (+/-)-r-7,t-8-dihydroxy-t-9,10-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene (BPDE-I). Unscheduled DNA synthesis exhibited a linear response to BPDE-I concentrations up to 1.5 microM and a saturation plateau after higher concentrations. Maximal unscheduled DNA synthesis was observed in the first hour after treatment with synthesis diminishing progressively thereafter. Half-maximal unscheduled DNA synthesis was seen within 4-6 h after treatment with 0.7 microM BPDE-I. DNA replication was inhibited by BPDE-I in a dose- and time-dependent fashion. The mechanisms of this inhibition were characterized by velocity sedimentation of pulse-labeled nascent DNA in alkaline sucrose gradients. Very low concentrations of BPDE-I (0.03 and 0.07 microM) were found to inhibit replicon initiation by up to 50% within 30-60 min after treatment. Recovery of initiation following these low concentrations was evident within 3 h after treatment. Higher concentrations of carcinogen inhibited DNA synthesis in active replicons. This effect was manifested by a reduction in incorporation of precursor into replication intermediates of greater than 1 X 10(7) Da with the concurrent production of abnormally small nascent DNA. When viewed 45 min after treatment with 0.17 microM BPDE-I the combination of these two effects partially masked the inhibition of replicon initiation. However, even after treatment with 0.33 microM BPDE-I an effect on initiation was evident. These results reveal a pattern of response to BPDE-I that is quite similar to that produced by 254 nm radiation.     

The influence of chromatin structure on initial DNA damage and radiosensitivity in CHO-K1 and xrs1 cells at low doses of irradiation 1-10 Gy

Mitotic compaction of chromatin was generated by treatment of cells with nocodazole. Alternatively, chromatin structure was altered by incubating cells in 500 mM NaCl. The irradiation response in the dose range of 1-10 Gy was measured by colony assay and by a modified fluorometric analysis of DNA unwinding (FADU) assay which measures the amount of undamaged DNA by EtBr fluorescence. Cell survival curves of irradiated CHO-K1 cells showed that treatment with nocodazole increases radiosensitivity as indicated by a decrease of the mean inactivation dose (D) from 4.446 to 4.376. Nocodazole treatment increased the initial radiation-induced DNA damage detected by the FADU assay from 7% to 13%. In repair-defective xrs1 cells, the same conditions increased the radiosensitivity from 1.209 to 0.7836 and the initial DNA damage from 43% to 57%. Alterations to chromatin structure by hypertonic medium increased radiosensitivity in CHO-K1 cells from of 4.446 to 3.092 and the initial DNA damage from 7% to 15%. In xrs1 cells these conditions caused radiosensitivity to decrease from 1.209 to 1.609 and the initial DNA damage to decrease from 43% to 36%. Disruption of chromatin structure by hypertonic treatment was found to be time-dependent. A threefold increase of exposure time to hypertonic medium from 40 to 120 min increased the initial DNA damage in CHO-K1 cells from 7% to 18% but decreased initial DNA damage in xrs1 cells from 43% to 21%. Perturbation of chromatin structure with hypertonic treatment has been shown to increase the radiosensitivity and the initial DNA damage in repair-competent CHO-K1 cells and decrease the radiosensitivity and DNA damage in repair-defective xrs1 cells. Hypertonic treatment thus abolishes differences in chromatin structure between cell lines and differences in initial DNA damage. Radiosensitivity and initial DNA damage are correlated ( r(2)=0.92; p=0.0026) and this correlation also holds when chromatin compaction is altered. The experiments demonstrate that initial DNA damage and chromatin structure are major determinants of radiosensitivity.     

DNA lesion-specific co-localization of the Mre11/Rad50/Nbs1 (MRN) complex and replication protein A (RPA) to repair foci

The DNA damage response, triggered by DNA replication stress or DNA damage, involves the activation of DNA repair and cell cycle regulatory proteins including the MRN (Mre11, Rad50, and Nbs1) complex and replication protein A (RPA). The induction of replication stress by hydroxyurea (HU) or DNA damage by camptothecin (CAMPT), etoposide (ETOP), or mitomycin C (MMC) led to the formation of nuclear foci containing phosphorylated Nbs1. HU and CAMPT treatment also led to the formation of RPA foci that co-localized with phospho-Nbs1 foci. After ETOP treatment, phospho-Nbs1 and RPA foci were detected but not within the same cell. MMC treatment resulted in phospho-Nbs1 foci formation in the absence of RPA foci. Consistent with the presence or absence of RPA foci, RPA hyperphosphorylation was present following HU, CAMPT, and ETOP treatment but absent following MMC treatment. The lack of co-localization of phospho-Nbs1 and RPA foci may be due to relatively shorter stretches of single-stranded DNA generated following ETOP and MMC treatment. These data suggest that, even though the MRN complex and RPA can interact, their interaction may be limited to responses to specific types of lesions, particularly those that have longer stretches of single-stranded DNA. In addition, the consistent formation of phospho-Nbs1 foci in all of the treatment groups suggests that the MRN complex may play a more universal role in the recognition and response to DNA lesions of all types, whereas the role of RPA may be limited to certain subsets of lesions.     

DNA isolation from forest soil suitable for PCR assays of fungal and plant rRNA genes

This protocol for DNA isolation from forest soil samples is advantageous because it uses only one liquid transference step and can process several samples with minimal time and equipment. The use of benzyl chloride early in the extraction protocol increases DNA yield and purity. The obtained DNA is useful for PCR amplification of nuclear and mitochondrial ribosomal related sequences from fungi and ribosomal DNA from plant chloroplasts. Isolated DNA can be used either undiluted or at low dilutions in PCR assays. A final glassmilk treatment of isolated DNA is useful to recover high molecular weight DNA fractions from agarose gel. DNA losses during glassmilk treatment can generate negative PCR results.     

Interleukin-2 induces the activities of DNA topoisomerase I and DNA topoisomerase II in HuT 78 cells

The induction by interleukin-2 of DNA topoisomerase I and DNA topoisomerase II activities in the human T cell line HuT 78 was investigated. HuT 78 cells were treated with 1000 U of interleukin-2/ml, and extracts of the HuT 78 nuclei were prepared over a 24 h period. The extracts were assayed quantitatively for the activities of DNA topoisomerase I and DNA topoisomerase II. Three concomitant, transient increases of 3- to 11-fold in the specific activities of both DNA topoisomerase I and DNA topoisomerase II were observed following treatment with IL-2 at 0.5, 4, and 10 h after treatment with interleukin-2. The specific activities of both enzymes returned to base-line values after each of these transient increases. These results reveal that the activities of DNA topoisomerase I and DNA topoisomerase II are highly regulated in HuT 78 cells upon treatment with IL-2.     

Single strand DNA catenane synthesis using the formation of G-quadruplex structure

DNA is a good material for constructing nanostructures such as DNA origami. One of the challenges in this field is constructing a topologically complex structure. Here, we synthesized a DNA catenane through the formation of a G-quadruplex structure. The formation of the DNA catenane was investigated by gel electrophoresis. Interestingly, the synthesized DNA catenane was destroyed by heat treatment. Because conventional methods to construct DNA catenane include enzymatic ligation or chemical reactions, DNA is cyclized by covalent bond connection and never destroyed by heat treatment. To our knowledge, this is the first report of the synthesis of DNA catenane without using covalent bonds. Our novel way of synthesizing DNA catenane may be of use in easily recoverable DNA topological labeling.     

Lack of DNA alterations induced by orotic acid in rat liver as evaluated with two DNA unwinding methods

One percent orotic acid supplemented diet is a promoting treatment in the rat model of liver carcinogenesis. After treatment with this type of diet, DNA alterations were observed using alkaline sucrose gradients and alkaline elution methods. In this work we have utilized two unwinding methods for the detection of DNA fragmentation. One method is a viscosimetric method in which the rate of increase in DNA viscosity with time is related to the rate of alkaline DNA unwinding. The second method measures fluorimetrically the amount of renatured and denatured DNA after different times allowed for alkaline DNA unwinding. These two methods are very sensitive in detecting DNA breaks induced by typical alkylating agents, X-rays and H2O2. The two unwinding methods were clearly negative for the orotic acid supplemented diet. We suggest that the DNA alterations detected with alkaline sucrose gradients and alkaline elution methods, after promoting treatment with orotic acid, are probably different from the DNA breaks induced by typical alkylating agents, X-rays and H2O2.