DNA strand breaks and DNA repair response in lymphocytes after chronic in vivo exposure to very low doses of ionizing radiation in mice

In contrast to the well-documented negative effects of high-dose oxidant exposure, accumulating evidence supports a positive, perhaps essential physiologic role for very low-level oxidant stress. For example, low-level oxidant exposure, within or below the physiologic range, has been reported to stimulate membrane signal transduction, proliferation, antioxidant defense and DNA repair. In the present study, we have examined whether whole-body exposure to low-dose radiation (LDR) results in an alteration in constitutive (steady state) levels of DNA-strand breaks and whether an adaptive increase in DNA-repair response is induced. C57B1/6J mice were exposed to 0.04 Gy (4 cGy) of gamma-radiation as a model of low level oxidant stress. End points measured after chronic in vivo LDR included: (1) constitutive expression of DNA-strand breaks in quiescent spleen cells; (2) sensitivity to DNA damage after high-dose radiation exposure in vitro; (3) repair of constitutive and radiation-induced DNA strand breaks after mitogen stimulation: (4) activity of the DNA-repair associated enzyme, poly(ADP-ribose)transferase (ADPRT) and its substrate, NAD. The results indicated that the constitutive expression of DNA-strand breaks is significantly decreased after chronic LDR; however, DNA-repair capacity after high-dose radiation exposure is not increased above that observed in sham-irradiated mice. Associated with the reduction in constitutive DNA-strand break accumulation was a decrease in resting levels of the DNA-repair-associated enzyme poly(ADP-ribose) transferase (ADPRT). These results are consistent with the interpretation that cumulative DNA damage and associated DNA-repair activity in unstimulated cells are both reduced after chronic LDR exposure.     

The effect of gossypol on the frequency of DNA-strand breaks in human leukocytes in vitro

Gossypol, a human antifertility agent isolated from the cotton plant, was found to induce a dose-dependent increase in the frequency of DNA-strand breaks in human leukocytes exposed to 2-40 micrograms/ml of the drug for 1 h in serum-free medium in vitro. DNA-strand breaks were studied by alkaline elution or alkaline unwinding of DNA followed by hydroxylapatite-chromatography. No decrease of gossypol-induced DNA-strand breaks was observed after post-treatment incubation times up to 24 h, whereas X-ray-induced DNA breaks disappeared within 2 h under the same incubation conditions. Cells exposed to gossypol in the presence of 10% fetal calf serum showed no or little increase of DNA breaks, suggesting that serum proteins inhibit the DNA-damaging activity of the drug. Both optical isomers of gossypol induced DNA-strand breaks. However, the effect of (-)-gossypol was only about half of that of (+)-gossypol and the racemic form. The induction and persistence of DNA-strand breaks by gossypol, as well as the reduction of this effect in the presence of serum should be considered in the evaluation of the potential in vivo genotoxicity of the drug.     

Studies of DNA-strand induced in human fibroblasts by chemical mutagens/carcinogens.

A method for the study of DNA-strand breaks using alkaline denaturation followed by hydroxylapatite chromatography has been modified and used for the detection of chemically induced DNA-strand breaks. A new procedure for the incubation of human fibroblasts with a metabolizing system and the detection of DNA-strans breaks is presented. With this method the induction and repair of DNA-strand breaks have been studied in human fibroblasts exposed to methyl methanesulphonate, melphalan, benzo[a]pyrene and cyclophosphamide. These agents all give rise to DNA-strand breaks. In cells exposed to methyl methanesulphonate, melphalan or benzo[a]pyrene these breaks disappeared within 21 h after re moval of the drug. In cells exposed to the bifunctional alkylating agent cyclophosphamide, studies of DNA-strand breaks suggest the presence of inter-strand cross links.     

Chromosome damage induced by decay of 3H and 125I incorporated into DNA of Chinese hamster cells

The present study was undertaken to compare the frequency of chromatid-type aberrations in Chinese hamster cells with previous results on accumulation of unrepaired DNA-strand breaks after incorporation of 3H-TdR or 125IUdR into DNA. A linear-quadratic function was fitted by the weighted-least-square method to the data on yield of chromatid aberrations at different dpm values. Based on a significant linear response at low doses, RBE for 125I in relation to 3H was calculated for (i) chromatid breaks (17 +/- 6), (ii) the sum of isochromatid breaks and chromatid exchanges (21 +/- 9), and (iii) the total number of chromatid aberrations (18 +/- 5). Analogously, the RBE for accumulation of DNA-strand breaks was determined (13 +/- 6). Our results are consistent with the assumption that chromosomal aberrations mainly originate from unrepaired DNA-strand breaks.     

DNA strand scission and ADP-ribosyltransferase activity during murine erythroleukemia cell differentiation

The accumulation of DNA strand breaks and activation of ADP-ribosyltransferase (ADPRT) have recently been associated with cellular differentiation. Murine erythroleukemia (MEL) cells undergo erythropoietic differentiation when exposed to dimethyl sulfoxide (Me2SO) and several studies have suggested that DNA strand scission induced by this agent is a prerequisite for expression of the differentiated phenotype. Me2SO induction of MEL cells has also been associated with increases in ADPRT activity in one study, but not in another. We have monitored the effects of Me2SO on DNA strand breaks in preformed and replicating MEL cell DNA. The results clearly demonstrate that DNA fragmentation is not detectable during Me2SO induction of MEL differentiation, even in the presence of 3-aminobenzamide, an inhibitor of ADPRT. Further, these results are consistent with an absence of detectable changes in both endogenous and total potential ADPRT activity during Me2SO-induced MEL differentiation. These findings would argue against Me2SO induction of DNA strand scission and ADPRT in MEL cells undergoing differentiation.     

Transient formation of DNA strand breaks during the induced differentiation of a human promyelocytic leukaemic cell line, HL-60.

During the induced differentiation of the human promyelocytic leukaemic cell line, HL-60, along the myelocytic lineage, DNA strand-breaks are formed. These breaks which are formed in the face of a proficient DNA repair mechanism, are only transiently maintained and subsequently become religated. The ligation of these breaks requires the activity of the nuclear adenosine diphosphoribosyl transferase (ADPRT). Inhibition of nuclear ADPRT, an enzyme totally dependent on the presence of DNA strand-breaks for its activity and required for efficient DNA repair in eukaryotic cells, blocks the religation of these breaks but not their formation. The inhibition of DNA strand ligation in the differentiating HL-60 cells results in loss of viability and cell death.     

Cell cycle effects on the basal and DNA-damaging-agent-stimulated ADPRT activity in cultured mammalian cells

ADP-ribosyl transferase (ADPRT) is a DNA-dependent chromatin-associated enzyme which covalently attaches ADP-ribose moieties derived from NAD+ to protein acceptors to form poly(ADP-ribose). ADPRT activity is strongly stimulated by breaks in DNA, and it is suggested that its activity is required for efficient DNA excision repair. In this paper, a cell-cycle-dependent fluctuation of basal ADPRT activity was demonstrated by measuring it in permeabilized FL cells. The cell used was subjected to arginine starvation for 48 h before being released from the block by replacement of deficient medium with complete medium and cells in different proliferating stages were traced by [3H]TdR pulse labelling and obtained at different intervals after block release. The peak basal ADPRT activity appeared 4-6 h after the appearance of the peak of DNA synthesis. After treating the cells with MNNG (10(-4) M), MMS (10(-3)-10(-4) M) and 4NQO (10(-5) M) for 90 min just after release of the block, the ADPRT activity was markedly stimulated. It was further demonstrated that the effects of MNNG/4NQO and cell cycle influence on the level of poly(ADP-ribose) synthesis appear to be additive. While concerning MMS, quite a different pattern of ADPRT stimulation in the cell cycle was demonstrated, i.e., the activity of ADPRT stimulation of 10(-3) M MMS was found to be completely dependent on the basal ADPRT activity. In the cells with the highest basal ADPRT activity 12 h after block release, the MMS-induced ADPRT stimulation could not be observed. It was suggested that more than one pathway might be present in ADPRT stimulation induced by DNA-damaging chemicals, and the cells synchronized in late G1 stage might be the most suitable for demonstrating poly(ADP-ribose) synthesis after DNA damage.     

Inhibition of poly(ADP-ribosyl)ation does not prevent lymphocyte entry into the cell cycle

The enzyme poly(ADP-ribosyl)transferase (ADPRT) becomes activated soon after a mitogenic stimulus is applied to lymphocyte cultures. It has also been reported that ADPRT inhibitors prevent cell proliferation when added to cultures at the same time as the mitogen. While this has been ascribed to the need to seal physiologically present DNA strand breaks before cells enter S phase, the presence of DNA strand breaks in quiescent human lymphocytes has been recently questioned. We demonstrate here that non-toxic concentrations of ADPRT inhibitors do not affect lymphocyte blastization and proliferation, as measured by thymidine incorporation and cytofluorimetry. We therefore suggest that ADPRT activation is required for late functions which are not needed for cell cycle progression.     

Mechanism of phorbol myristate acetate-induced lymphotoxin production by a human T cell hybridoma

Various hydroxyl radical scavengers markedly inhibited phorbol myristate acetate (PMA)-induced lymphotoxin (LT) production by a human T cell hybridoma, AC5-8. Among those we tested, tetramethylurea (TMU) was the most potent scavenger, and it was revealed that TMU must be added before 2 h have elapsed after PMA addition in order for LT production to be inhibited. In concordance with this fact, soluble NADPH dependent O2- forming enzyme(s) were activated several fold by PMA. PMA also induced DNA strand breaks, a process markedly inhibited by TMU. As expected, ADP-ribosyl transferase (ADPRT), which is well known to require DNA strand breaks for its enzymatic activity, was activated by PMA treatment. In addition, specific inhibitors for ADPRT, namely 3-amino-benzamide and nicotinamide, inhibited PMA-induced LT production. Taken together, these three successive events, activation of soluble NADPH dependent O2- forming enzyme(s), DNA strand breaks and activation of ADPRT, may be required for PMA-induced LT production by AC5-8.     

DNA strand breaks and repair synthesis in Yoshida sarcoma cells with differential sensitivities to bifunctional alkylating agents and UV light

The induction of DNA-strand breaks and repair synthesis has been examined in cultured Yoshida sarcoma cell lines sensitive (YS) and resistant (YR) to methylene dimethanesulphonate (MDMS). Using an alkaline DNA unwinding-hydroxylapatite technique, we were able to detect breaks in DNA immediately after MDMS treatment and at similar levels in both YS and YR cells. MDMS treatment and post-treatment incubation in the presence of 1-β-D-arabino-furanosylcytosine (araC) lead to a large increase in the numbers of breaks when compared with MDMS treatment alone which indicated that many of the DNA-strand breaks seen after MDMS treatment were intermediates in excision repair. The magnitude of break incidence with the araC treatment was again equal in YS and YR cells indicating that these 2 lines made enzymic incision next to MDMS-induced lesions with equal capacities.During incubation following MDMS treatment, the levels of DNA-strand breaks in YR cells were found to decrease more rapidly than in YS cells. Parallel DNA-repair synthesis estimations, using BND-cellulose chromatography, revealed that the increased rate of decline in breaks in YR cells was accompanied by an increase in repair-synthesis activity compared to YS cells. This was interpreted as indicating that an intermediate step in an excision-repair pathway for MDMS-induced lesions was relatively deficient in YS compared to YR cells.A similar difference in the rates of decline of DNA-strand breaks between YS and YR cells was also observed following treatment with UV light to which MDMS-resistant YR cells also display cross-resistance. However, no such difference was detected following treatment with the monofunctional alkylating agent, methyl methanesulphonate, to which YS and YR cells are equally sensitive. These results suggest that resistance to MDMS in the YR cell line is achieved by an increased efficiency in the gap-sealing component of the excision-repair process.     

Effects of 3-aminobenzamide on the rejoining of DNA-strand breaks in mammalian cells exposed to methyl methanesulphonate; role of poly(ADP-ribose) polymerase

The effect of 3-aminobenzamide (3AB), an inhibitor of poly(ADP-ribose) polymerase, on DNA-repair processes has been investigated after treating V79 hamster cells with methyl methanesulphonate (MMS). Repair activity was observed as changes in DNA-strand break levels. MMS induces transient strand breaks, the level of which slowly decreases with time. Addition of 3AB leads to a rapid increase in the number of breaks. The level of breaks increases linearly with time until it suddenly levels off. Increasing the concentration of 3AB does not change the slope of this curve, but the steady-state level of breaks increases. The incision-rejoining kinetics indicates that 3AB induces a delay in the strand-break rejoining process. In the absence of 3AB the breaks have a lifetime of 1-2 min and this is increased by a factor of 5 in the presence of 5 mM 3AB.     

Indirect mechanism of lead-induced genotoxicity in cultured mammalian cells

The data concerning the mutagenic, clastogenic and carcinogenic properties of inorganic lead compounds have been conflicting. To investigate whether the genotoxicity of lead is due to indirect effects such as interference with DNA-repair processes, the induction of mutations, sister-chromatid exchanges and strand breaks by lead ions alone as well as in combination with UV light as a standard mutagen were determined. Lead acetate alone does not induce DNA-strand breaks in HeLa cells or mutations at the HPRT locus and sister-chromatid exchanges in V79 Chinese hamster cells. However, at all endpoints tested, lead ions interfere with the processing of UV-induced DNA damage. They inhibit the closing of DNA-strand breaks after UV irradiation and enhance the number of UV-induced mutations and sister-chromatid exchanges, indicating an inhibition of DNA repair. These data point out the necessity to consider such indirect effects when assessing the genotoxicity of metal compounds. As possible mechanisms of repair inhibition we suggest either the interaction with repair enzymes such as polymerase or ligase or else the interaction with calcium-regulated processes, for example with calmodulin.     

DNA strand breaks and mutations caused by penbutolol, a beta blocker

Sixteen beta-adrenergic receptor blockers were screened for their mutagenic potential using Salmonella typhimurium strains TA98 and TA100. All except penbutolol were found to be nonmutagenic. Penbutolol was cytotoxic to human fibroblasts and Chinese hamster V79 cells. These effects could be due to its ability to induce DNA-strand breaks detected by hydroxyapatite chromatography, which remained unrepaired within 1 h of incubation. Under the same conditions strand-breaking activity of propranolol, timolol and indenolol could not be detected. Three potential impurities of penbutolol were ineffective in causing DNA-strand breakage and one metabolite of this drug was found to be nonmutagenic.     

ADP-ribosylation is involved in the integration of foreign DNA into the mammalian cell genome.

The most commonly used DNA transfection method, which employs the calcium phosphate co-precipitation of the donor DNA, involves several discrete steps (1,2). These include the uptake of the donor DNA by the recipient cells, the transport of the DNA to the nucleus, transient expression prior to integration into the host cell genome, concatenation and integration of the transfected DNA into the host cell genome and finally the stable expression of the integrated genes (2,3). Both the concatenation and the integration of the donor DNA into the host genome involve the formation and ligation of DNA strand-breaks. In the present study we demonstrate that the nuclear enzyme, adenosine diphosphoribosyl transferase (ADPRT, E.C. 2.4.2.30), which is dependent on the presence of DNA strand breaks for its activity (4,5) and necessary for the efficient ligation of DNA strand-breaks in eukaryotic cells (4,6), is required for the integration of donor DNA into the host genome. However, ADPRT activity does not influence the uptake of DNA into the cell, its episomal maintenance or replication, nor its expression either before or after integration into the host genome. These observations strongly suggest the involvement of ADPRT activity in eukaryotic DNA recombination events.     

Hypochlorous acid potentiates hydrogen peroxide-mediated DNA-strand breaks in human mononuclear leucocytes.

In this study the formation of DNA single-strand breaks in MNL in close proximity to activated phagocytes, or in contact with added H2O2 and/or HOCl, were evaluated. Neutrophils activated by phorbol myristate acetate (PMA), induced DNA-strand breaks in neighboring lymphocytes which increased after 1-2 h incubation in a repair medium. These DNA-strand breaks could be prevented by the addition of catalase or substitution of the neutrophils with cells from a patient with chronic granulomatous disease. Inclusion of the myeloperoxidase (MPO) inhibitor, sodium azide (NaN3), to the system was associated with less damage after 1-2 h incubation and a faster repair rate. Exposure of MNL to added reagent H2O2 (12-100 microM) was also accompanied by DNA damage. Addition of reagent HOCl (3-25 microM) did not induce any DNA-strand breaks. However, when combined with H2O2 (12.5 microM), HOCl increased H2O2-mediated DNA damage and compromised the repair process. Interactions between the phagocyte-derived reactive oxidants H2O2 and HOCl are probably involved in the etiology of inflammation-related cancer.     

ADP-核糖基转移酶的抑制对γ线所致肿瘤细胞DNA损伤的加强作用

本文探讨了ADP—核糖基转移酶(ADPRT)的活性、DNA单链断裂(SSB)重接和细胞潜在致死质损伤修复(PLDR)三者的关系。证明了ADPRT的特异性抑制剂3—氨基苯甲酰胺(3AB)能阻抑γ线所致的小鼠腹水瘤细胞DNA SSB的重接和PLDR。为增强放射治疗的效果提供了可能的新途径。     

The effect of deuterium labeling on the genotoxicity of N-nitrosodimethylamine, epichlorohydrin and dimethyl sulfate

Deuterated and non-deuterated N-nitrosodimethylamine, epichlorohydrin and dimethyl sulfate were evaluated for the ability to induce DNA single-strand breaks in rat hepatocytes as measured by alkaline elution. Non-deuterated nitrosodimethylamine induced twice the amount of DNA-strand breaks as the deuterated form. No evidence of a deuterium isotope effect was seen for the direct-acting alkylating agents epichlorohydrin and dimethyl sulfate.     

Effects of pre-treatment with sodium butyrate on the frequencies of X-ray-induced chromosomal aberrations in human peripheral blood lymphocytes

The effects of sodium butyrate-mediated alterations in chromatin structure on the yields of X-ray-induced chromosomal aberrations were studied in human peripheral blood lymphocytes. Unstimulated (G0) lymphocytes were pre-treated with sodium butyrate (5 mM) for 24 h, X-irradiated and then stimulated to pass through the cell cycle. Cells in their first post-radiation metaphase were scored for chromosomal aberrations. In parallel biochemical experiments nucleoid sedimentation technique was used to examine the induction and repair of DNA-strand breaks. The results show that sodium butyrate pre-treatment leads to a significant increase in the frequencies of dicentrics and rings, but not of fragments. The data from biochemical studies suggest that the numbers and rates of repair of X-ray-induced DNA-strand breaks are the same in butyrate-treated and untreated cells. We therefore suggest that the observed effect is probably a consequence of butyrate-induced conformational changes in the chromatin of G0 lymphocytes.     

DNA repair in human promyelocytic cell line, HL-60.

The human promyelocytic cell line, HL-60, shows large changes in endogenous poly(ADP-ribose) and in nuclear ADP-ribosyl transferase activity (ADPRT) during its induced myelocytic differentiation. DNA strand-breaks are an essential activator for this enzyme; and transient DNA strand breaks occur during the myelocytic differentiation of HL-60 cells. We have tested the hypothesis that these post-mitotic, terminally differentiating cells are less efficient in DNA repair, and specifically in DNA strand rejoining, than their proliferating precursor cells. We have found that this hypothesis is not tenable. We observe that there is no detectable reduction in the efficiency of DNA excision repair after exposure to either dimethyl sulphate or gamma-irradiation in HL-60 cells induced to differentiate by dimethyl sulphoxide. Moreover, the efficient excision repair of either dimethyl sulphate or gamma-irradiation induced lesions, both in the differentiated and undifferentiated HL-60 cells, is blocked by the inhibition of ADPRT activity.     

Rejoining of DNA strand breaks is an early nuclear event during the stimulation of quiescent lymphocytes

Activation of quiescent human peripheral blood lymphocytes or purified T cells by the mitogen, phytohemagglutinin (PHA), involves a rapid rejoining of DNA breaks present in the resting cells as detected by both nucleoid sedimentation analysis and rate of strand unwinding in alkali. Inhibitors of the enzyme ADP-ribosyltransferase (ADPRT) prevent activation of peripheral lymphocytes or T cells by PHA or concanavalin A in a dose-dependent manner, but only if present during the early stages. They do not affect subsequent proliferation if added later, nor do they inhibit the growth of lymphoblastoid cell lines. The inhibitors slow the rejoining of DNA breaks but do not affect the binding of mitogen to the cell surface or the early PHA-stimulated turnover of plasma membrane inositol phospholipids. DNA breaking and rejoining, regulated by ADPRT, may be involved in controlling gene expression during differentiation.