The repair of x-ray-induced chromosome aberrations in stimulated and unstimulated human lymphocytes

The repair time for chromosome breaks induced by X-irradiation of unstimulated (G₀) and stimulated (G₁) human lymphocytes has been determined by dose fractionation studies. In both types of cells repair time was approx. 4–5 h. Treatment with hydroxyurea, a DNA synthesis inhibitor, did not prevent or delay the rejoining of broken chromosomes, whereas treatment with cycloheximide, a potent protein synthesis inhibitor, did. Thus, the repair of radiation-induced chromosome breaks in human lymphocytes is similar to the repair observed with plant cells.     

Early nuclear events in lymphocyte proliferation : The role of DNA strand break repair and ADP ribosylation

The previously reported extensive DNA strand breakage in resting murine splenic lymphocytes is not an artifact of the extraction or assay procedure. The benzamide inhibitors of poly(ADP ribose) synthetase (pADPRS), such as 5-methoxybenzamide (MBA), had been shown to block the strand break repair occurring within 2 h of activation of splenic lymphocytes by the mitogen concanavalin A (conA); the inhibitors also blocked early events in proliferation, such as blast formation, as well as entry into S phase. Inhibitors of pADPRS blocked lymphocyte proliferation by inhibiting the activity of this enzyme, rather than by non-specific effects. Aphidicolin, an inhibitor of alpha-polymerase, also prevented DNA strand break repair in conA-stimulated cells but, unlike MBA, did not prevent blast formation. DNA strand breaks accumulated in the presence of MBA at the same linear rate (300-400/h) in both resting and conA-treated cells. We and others had hypothesized that this accumulation was due to a continuous production of strand breaks in lymphocytes, leading to their accumulation in presence of repair inhibitors. However, incubation of the cells with aphidicolin at concentrations that inhibited repair did not result in any increase in strand breaks. The hypothesis of continuous cycling of breaks is incorrect; accumulation of breaks was due to some indirect effect of MBA, such as a possible disinhibition of an ADP-ribosylation-sensitive endonuclease described in other cell types. All of the early stages of lymphocyte proliferation, including blast transformation (but not DNA synthesis) require ADP ribosylation. Repair of DNA strand breaks is not a precondition for blast formation, though experiments involving the combined effects of MBA and aphidicolin showed that repair of the breaks is essential in order for the cells to replicate their DNA. Our data are consistent with a model suggesting that DNA strand breaks introduced into differentiated cells act as an additional safety-catch mechanism that restrains them from replicating their genetic material but not from undergoing the early stages of proliferation.     

Apoptosis of unstimulated human lymphocytes and DNA strand breaks induced by the topoisomerase II inhibitor etoposide (VP-16)

Etoposide (VP-16)-induced DNA strand breaks and repair and apoptosis of unstimulated human lymphocytes have been studied using DNA comet assay, electrophoresis of low-molecular-weight DNA extracts, and fluorescence microscopy. Incubation of unstimulated human lymphocytes with VP-16 (50-200 microg/ml) for 3 or 24 h induced apoptosis. This conclusion is supported by results of morphological studies, evaluation of the proportion of hypodiploidy and internucleosomal degradation of DNA in lymphocytes. Etoposide-induced formation of DNA strand breaks preceded the appearance of these conventional apoptotic manifestations. The number of single-strand breaks depended on VP-16 concentration, and 2-3 h after its removal from the incubation medium they were repaired. The hydroxyl group at the C-4; position of the etoposide dimethoxyphenol ring may be responsible for the formation of single-strand breaks. Double-strand breaks were unrepaired 20 h after the change of the incubation medium. The number of double-strand breaks and a proportion of apoptotic cells did not exhibit any dependence on VP-16 concentration and/or duration of cell exposure to this agent. We suggest that the cytotoxic effect of VP-16 on unstimulated lymphocytes is mediated by a topoisomerase II isoform, topoisomerase II-beta, which is localized in the nucleolus and is not related to the cell cycle.     

Inhibition of DNA repair by deoxyadenosine in resting human lymphocytes

Profound lymphopenia is characteristic of immunodeficient children who lack adenosine deaminase (ADA). When ADA is inactive, deoxyadenosine (dAdo) is phosphorylated by immature T lymphoblasts and inhibits cell division. However, dAdo also causes the slow accumulation of DNA strand breaks in nondividing, mature human peripheral blood lymphocytes. To explore the basis for this phenomenon, we have assessed the effects of dAdo and other deoxynucleosides on the repair of gamma-radiation induced DNA strand breaks in resting normal lymphocyte cultures. As measured by a sensitive DNA unwinding assay, most DNA strand breaks were rejoined within 2 hr after exposure of lymphocytes to 500 rad. In medium supplemented with deoxycoformycin, a tight binding ADA inhibitor, dAdo retarded DNA rejoining in a dose and time dependent manner. The inhibition required dAdo phosphorylation. Over an 8-hr period, 10 microM dAdo gradually rendered peripheral blood lymphocytes incompetent for DNA repair. Among several other compounds tested, 2-chlorodeoxyadenosine, an ADA resistant dAdo congener with anti-leukemic and immunosuppressive activity, was the most powerful inhibitor of DNA repair, exerting significant activity at concentrations as low as 100 nM. Both dAdo and 2-chlorodeoxyadenosine blocked unscheduled DNA synthesis in irradiated resting lymphocytes, as measured by [3H]thymidine uptake. On the basis of this and other data, we suggest that quiescent peripheral blood lymphocytes break and rejoin DNA at a slow and balanced rate. The accumulation of dATP progressively retards the DNA repair process and thereby fosters the time-dependent accretion of DNA strand breaks. By inhibiting DNA repair, dAdo, 2-chlorodeoxyadenosine and related compounds may substantially potentiate the toxicity of DNA damaging agents to normal and malignant lymphocytes.     

The effect of aphidicolin on DNA repair in resting and mitogen stimulated human lymphocytes

Aphidicolin inhibits DNA repair in human lymphocytes as measured by unscheduled DNA synthesis and the rejoining of strand breaks. When the lymphocytes are mitogen stimulated, sensitivity of DNA repair towards aphidicolin decreases, possibly due to the induction of the beta DNA polymerase.     

DNA repair replication,DNA breaks and sister-chromatid exchange in human cells treated with adriamycin in vitro

The effects of adriamycin (AM) on DNA repair replication, the frequency of sister-chromatid exchange (SCE), the rate of cell proliferation and the frequency of DNA strand breaks were studied in human cells in vitro. No repair replication was observed in lymphocytes exposed to AM in concentrations up to 10^?3 moles/1. DNA repair replication induced by UV and alkylating agents was not affected by a concentration of AM that completely inhibited cell proliferation (10^?6 moles/1).Fibroblasts exposed to AM at 10^?4 moles/1 in the presence of hydroxyurea showed an increase of strand breaks and cross-links in DNA. When AM was added to UV-irradiated fibroblasts, there was an increase of DNA strand breaks in addition to the breaks caused by UV alone. Similar effects were observed in lymphocytes.A dose-dependent increase of SCE was observed in lymphocytes exposed to low concentrations of AM (<10^?7 moles/1). At higher concentrations the increase of SCE levelled off, and cell proliferation became severely inhibited. There was no evidence of removal of SCE-inducing damage in cells exposed to AM during G₀ or G₁. The level of SCE induced in the third cell cycle after treatment with AM was not different from that induced during the first two cell cycles.These results suggest that the various genotoxic and cytotoxic effects of AM are caused by different types of cellular damage. Moreover, AM-induced DNA damage persists for several cell cycles in human cells in vitro and seems to be resistant to repair activity.     

DNA repair in lymphocytes from patients with secondary leukemia as measured by strand rejoining and unscheduled DNA synthesis

The ability to repair damage to DNA was compared in 2 groups of patients having undergone treatment for leukemia, one of which developed secondary leukemia (SL), and the other without signs of secondary malignancy (treated controls). Both were related to normal controls. DNA repair was assessed in isolated peripheral lymphocytes from the patients by measuring the rejoining of strand breaks following alkylation damage to the lymphocytes or by measuring unscheduled DNA synthesis. Day-to-day variability in the assays was considerable, but findings were that 5 out of 7 SL patients had repair deficiencies as measured by their ability to rejoin strand breaks, and 5 out of 7 had increased unscheduled DNA synthesis compared to treated and normal controls. All patients with SL and 4 out of 8 treated controls had inherent strand breaks in their DNA as compared to the normal controls when measured by alkaline elution.     

The effect of deoxynucleosides on repair of DNA breaks in UVC-irradiated human lymphocytes

UVC irradiation of mammalian cells induces DNA lesions, which can give rise to transient DNA breaks at subsequent incubation of the cells. The yield of these transient DNA breaks depends on the incision rate as well as on the polymerase and ligation rates. It has previously been shown that the yield of transient DNA breaks is drastically lowered in human lymphocytes if the 4 deoxynucleosides are added to the culture medium during the repair period after UVC irradiation. The present results show that addition of the combination dAdo dGuo dThd or addition of the combination dAdo dThd also efficiently reduces the yield of transient DNA breaks during a repair period of 3 h after the UVC irradiation. Other combinations of deoxynucleosides are less efficient or not efficient at all. This indicates that the pool sizes of dATP and dTTP affect the yield of transient DNA breaks in human lymphocytes. However, the present data also indicate that the number of processed repair sites does not increase during the repair period after UVC irradiation, if the combination dAdo dThd is present in the culture medium during the repair period. Therefore, it is proposed that the presence of dAdo dThd affects the rate of insertion of repair patches but not the total amount of synthesized and inserted patches.     

DNA strand breaks, NAD metabolism, and programmed cell death

An intimate relationship exists between DNA single-strand breaks, NAD metabolism, and cell viability in quiescent human lymphocytes. Under steady-state conditions, resting lymphocytes continually break and rejoin DNA. The balanced DNA excision-repair process is accompanied by a proportional consumption of NAD for poly(ADP-ribose) synthesis. However, lymphocytes have a limited capacity to resynthesize NAD from nicotinamide. An increase in DNA strand break formation in lymphocytes, or a block in DNA repair, accelerates poly(ADP-ribose) formation and may induce lethal NAD and ATP depletion. In this way, the level of DNA single-strand breaks in the lymphocyte nucleus is linked to the metabolic activity of the cytoplasm. The programmed removal of lymphocytes (and perhaps of other cells) with damaged DNA, may represent a novel physiologic function for poly(ADP-ribose)-dependent NAD cycling.     

Genotoxicity of formaldehyde and an evaluation of its effects on the DNA repair process in human diploid fibroblasts

Formaldehyde treatment of human fibroblasts gave rise to DNA damage detected by a nick translation assay. This damage was not repaired by typical 'long-patch'-type excision repair as evidenced by the failure of DNA repair inhibitor post-treatment to elevate the amount of DNA strand breakage. In addition, the effects of formaldehyde on DNA repair were examined in light of a recent report suggesting that formaldehyde inhibited the repair of X-ray-induced strand breaks and UV- and benzo [a]pyrene diol epoxide-induced unscheduled DNA synthesis in human bronchial cells. We report that formaldehyde (1) was ineffective at inhibiting the sealing of X-ray- or bleomycin-induced DNA strand breaks, (2) did not inhibit the removal of pyrimidine dimers from cellular DNA at short treatment times, and (3) that the previously observed inhibition of unscheduled DNA synthesis was most likely due to the inhibition of uptake of labeled precursor into formaldehyde-treated cells. Thus, our findings are not consistent with the notion that formaldehyde inhibits the repair process in human fibroblasts. Finally, formaldehyde was shown to elevate the level of misincorporation of bases into synthetic polynucleotides catalyzed by E. coli DNA polymerase I, indicating that the mutagenicity of formaldehyde may be due to covalent alteration of DNA bases.     

Delayed repair of DNA single-strand breaks does not increase cytogenetic damage

DNA damage and cytogenetic effects of ionizing radiation were investigated in Chinese hamster ovary (CHO) cells and unstimulated human peripheral blood lymphocytes. DNA damage and repair were analysed by alkaline elution under conditions that predominantly measured DNA single-strand breaks (ssb). X-radiation (2.5 Gy) induced ssb in both CHO cells and unstimulated lymphocytes, and the breaks were repaired within 30 and 90 min, respectively. This rapid repair was delayed by the poly(ADP-ribose) polymerase inhibitor, 3-aminobenzamide (3AB). The cytogenetic effects of the 3AB-induced delay in DNA repair were examined by analysing sister chromatid exchange (SCE) frequency in CHO cells and fragmentation of prematurely condensed chromosomes (PCC) in unstimulated human lymphocytes after 2.5 Gy of X-rays. Although 3AB delayed the rejoining of DNA ssb, this delay did not result in increased cytogenetic damage manifested as either SCE or fragmentation of PCC. These results indicate that the rapidly rejoining DNA ssb are not important in the production of chromosome damage.     

Dependence of cell survival on DNA repair in human mononuclear phagocytes.

Mononuclear phagocytes play a central role in the pathogenesis of chronic inflammatory diseases. It is therefore important to define chemotherapeutically exploitable metabolic pathways that distinguish monocytes from other cell types. Blood monocytes do not synthesize deoxynucleotides de novo, and their transformation to macrophages occurs without cell division. Whether or not monocytes can repair DNA damage, and whether or not DNA repair is necessary for their survival, is unknown. The present experiments demonstrate that normal human monocytes, unlike neutrophils, rapidly repair DNA strand breaks induced by gamma-irradiation. Monocyte extracts contain functional immunoreactive DNA polymerase-alpha. DNA repair synthesis in normal monocytes is blocked by aphidicolin, an inhibitor of DNA polymerase-alpha with respect to dCTP. Aphidicolin is also directly toxic to normal monocytes, but has no effect on nondividing lymphocytes or fibroblasts. Compared to most other cell types, monocytes and macrophages have very low dCTP pools, but abundant deoxycytidine kinase activity. This suggests that dCTP derived from salvage pathways is important for DNA repair in these cells. Consistent with this notion, exogenous deoxycytidine could partially protect monocytes from aphidicolin killing. The unexpected toxicity of aphidicolin toward normal human monocytes may be attributable to their high rate of spontaneous DNA strand break formation, to the importance of DNA polymerase-alpha for DNA repair in these cells, and to their minute dCTP pools.     

Characterization of human poly(ADP-ribose) polymerase with autoantibodies

The addition of poly(ADP-ribose) chains to nuclear proteins has been reported to affect DNA repair and DNA synthesis in mammalian cells. The enzyme that mediates this reaction, poly(ADP-ribose) polymerase, requires DNA for catalytic activity and is activated by DNA with strand breaks. Because the catalytic activity of poly(ADP-ribose) polymerase does not necessarily reflect enzyme quantity, little is known about the total cellular poly(ADP-ribose) polymerase content and the rate of its synthesis and degradation. In the present experiments, specific human autoantibodies to poly(ADP-ribose) polymerase and a sensitive immunoblotting technique were used to determine the cellular content of poly(ADP-ribose) polymerase in human lymphocytes. Resting peripheral blood lymphocytes contained 0.5 X 10(6) enzyme copies per cell. After stimulation of the cells by phytohemagglutinin, the poly(ADP-ribose) polymerase content increased before DNA synthesis. During balanced growth, the T lymphoblastoid cell line CEM contained approximately 2 X 10(6) poly(ADP-ribose) polymerase molecules per cell. This value did not vary by more than 2-fold during the cell growth cycle. Similarly, mRNA encoding poly(ADP-ribose) polymerase was detectable throughout S phase. Poly(ADP-ribose) polymerase turned over at a rate equivalent to the average of total cellular proteins. Neither the cellular content nor the turnover rate of poly(ADP-ribose) polymerase changed after the introduction of DNA strand breaks by gamma irradiation. These results show that in lymphoblasts poly(ADP-ribose) polymerase is an abundant nuclear protein that turns over relatively slowly and suggest that most of the enzyme may exist in a catalytically inactive state.     

Inhibitors of repair DNA synthesis.

We have measured repair DNA synthesis in UV-irradiated normal human fibroblasts, grown to a defined state of quiescence in order to avoid the problem of discriminating repair from replicative DNA synthesis. We have assessed the effects of various DNA synthesis inhibitors on repair. Inhibition of repair synthesis by hydroxyurea, 1-beta-D-arabinofuranosylcytosine and aphidicolin is associated with the ability to accumulate DNA breaks due to enzymic incision at DNA damage sites; the inhibition by novobiocin is in accord with its known ability to block incision.     

Detection of alkylation damage in human lymphocyte DNA with the comet assay

The enzyme 3-methyladenine DNA glycosylase II (AlkA) is a bacterial repair enzyme that acts preferentially at 3-methyladenine residues in DNA, releasing the damaged base. The resulting baseless sugars are alkali-labile, and under the conditions of the alkaline comet assay (single cell gel electrophoresis) they appear as DNA strand breaks. AlkA is no t lesion-specific, but has a low activity even w ith undamagedbases. We have tested the enzyme at different concentrations to find conditions that maximise detection of alkylated bases with minimal attack on normal, undamaged DNA. AlkA detects damage in the DNA of cells treated with low concentrations of methyl methanesulphonate. We also find low background levels of alkylated bases in normal human lymphocytes.     

DNA damage in HeLa S3 cells by an antitumor drug ledakrin and other antitumor 1-nitro-9-aminoacridines

Ledakrin and seven other antitumor and cytotoxic derivatives of 1-nitro-9-aminoacridine were shown to induce DNA-single strand breaks in HeLa S3 cells as found by alkaline sucrose gradient centrifugation. The induced DNA damage is of non-random character. Some of Ledakrin-induced DNA breaks are probably generated by endonucleolytic cleavage in the course of repair processes as indicated by experiments with Novobiocin, an antibiotic preventing the incision step of DNA repair. Other Ledakrin-induced DNA breaks observed on alkaline sucrose gradients may arise from alkali-labile sites in DNA. Most of such sites seem to be converted to breaks after brief exposure to alkali. The extent of DNA damage by 1-nitro-9-aminoacridines was found to be correlated with cytotoxic activities of these compounds against HeLa S3 cells. Furthermore, Ledakrin and other derivatives seem to induce DNA-repair synthesis in HeLa S3 cells as judged by the stimulation of hydroxyurea (HU)-resistant incorporation of [³H] thymidine into DNA. The agents studied differ in their concentrations required to produce a considerable stimulation of DNA repair, whereas the maximal level of this effect is similar for all the derivatives assayed. The former values are correlated with cytotoxic activites of these compounds and seem to reflect the overall extent of DNA damage by 1-nitro-9-aminoacridines. Stimulation of DNA-repair synthesis is gradually shut off during prolonged incubation of the cells with Ledakrin or during postincubation of the cells in a drug-free medium. Such postincubation results also in the gradual accumulation of DNA-single strand breaks as observed by alkaline sucrose centrifugation. Hence, HeLa S3 cells are incapable of efficiently removing DNA damage by 1-nitro-9-aminoacridines, though the drug's action activates temporarily some repair mechanisms.The reported results suggest that overall DNA damage may contribute to the cytotoxic effects of 1-nitro-9-aminoacridines besides previously found ability of these agents to form interstrand DNA cross-links.     

Induction of an abortive and futile DNA repair process in E. coli by the antitumor DNA bifunctional intercalator, ditercalinium: role in polA in death induction.

Ditercalinium, an antitumor bifunctional intercalator which forms a high affinity reversible complex with DNA, was found to be specifically cytotoxic for polA and lig7 E. coli strains. In the polA strain, the cytotoxic effect of ditercalinium was suppressed by the uvrA mutation. DNA single strand breaks accumulated in presence of ditercalinium at high temperature in lig7 strains but not in polA strains. Ditercalinium caused no DNA synthesis inhibition although it was able to induce SOS functions. It is proposed that the ditercalinium DNA complex because of its non covalent nature acts as a dummy lesion for the UV repair system in E. coli leading to a futile and abortive repair process. Polymerase I appears to be required to prevent the malfunctioning of a DNA repair process triggered by molecules forming non covalent complex with DNA.     

Characterization of Excision Repair in Neurospora crassa

The excision of pyrimidine dimers from the deoxyribonucleic acid (DNA) of Neurospora crassa was examined. Postirradiation incubation in the presence of several chemicals known to inhibit various repair systems indicated that caffeine reduced the rate of excision twofold, but did not inhibit excision completely as did proflavine and quinacrine. Examination of the time course of excision showed that repair occurs at a relatively rapid rate: approximately 60 dimers excised per min after 500 ergs/mm(2). Further evidence for rapid excision was obtained by sedimentation analysis of DNA; the maximal number of breaks introduced during repair was three, suggesting that breaks are repaired almost as fast as they are made and that only a few dimers are repaired at a time. Repair synthesis was measured by prelabeling the DNA with (15)N and D(2)O, and then subjecting the DNA to equilibrium density gradient centrifugation after postirradiation incubation with (32)P. Accumulation of single-strand breaks with increasing dose of ultraviolet radiation suggested that the limiting step was subsequent to the incision and excision steps of repair. Equilibrium CsCl centrifugation demonstrated that the limiting step in excision was repair synthesis.