Mammalian topoisomerase II activity is modulated by the DNA minor groove binder distamycin in simian virus 40 DNA

DNA topoisomerases II are nuclear enzymes that have been identified recently as targets for some of the most active anticancer drugs. Antitumor topoisomerase II inhibitors such as teniposide (VM-26) produce enzyme-induced DNA cleavage and inhibition of enzyme activity. By adding to such reactions distamycin, a compound whose effects on DNA have been extensively characterized, we investigated the effects of drug binding upon topoisomerase II-mediated DNA cleavage induced by VM-26. We have found a correspondence between distamycin binding (determined by footprinting analysis) and topoisomerase II-mediated cleavage of SV40 DNA (determined by sequencing gel analysis). Distamycin binding potentiated the cleavage of specific sites in the near proximity of distamycin-binding sites (within at least 25 base pairs), which indicates that DNA secondary structure is involved in topoisomerase II-DNA interactions. That distamycin potentiated cleavage only at sites that were recognized in the absence of distamycin and suppressed cleavage directly at distamycin-binding sites indicates that topoisomerase II recognizes DNA on the basis of primary sequence. In addition, distamycin stimulated topoisomerase II-mediated DNA relaxation and antagonized the inhibitory effect of VM-26. These results show that the DNA sequence-specific binding of distamycin produces local and propagated effects in the DNA which markedly affect topoisomerase II activity.     

A polymerase chain reaction-based method to detect cisplatin adducts in specific genes.

Every bulky lesion in DNA can potentially inhibit the Taq DNA polymerase and thereby decrease the amplification produced in the polymerase chain reaction. We investigated the feasibility of using this inhibition to quantify DNA lesions produced by the anticancer drug cisplatin. Products were detected by electrophoresis followed by ethidium bromide staining. Quantitation was obtained by including [32P]dCTP in the amplification reaction and subsequently assessing the incorporated radioactivity. Hamster genomic DNA was platinated in vitro to defined levels and amplified with primers that produce either a 150, 750 or 2,000 base pair fragment. The degree of inhibition of PCR agreed with the predicted level of DNA platination in each size of fragment, suggesting that the polymerase was inhibited by every cisplatin-induced lesion. This method was used to detect cisplatin-induced lesions in the adenine phosphoribosyltransferase gene of CHO cells. Cells were incubated with 0-125 microM cisplatin for 2 h, the DNA was purified and subjected to PCR. A significant decrease in amplification of the 2 kbp fragment was observed in DNA from cells incubated with cisplatin at 75 microM. The degree of inhibition agreed closely with the amount of DNA damage in the overall genome as measured by atomic absorption. No change was detected in amplification of the 150 base fragment which can therefore be used to normalize data for any variations between DNA samples. This assay has the same sensitivity as other methods currently used for the analysis of gene-specific damage. The advantage of this assay is that it obviates the need for specific endonuclease complexes to recognize and cleave DNA adducts as previously required when analyzing damage in specific genomic sequences.     

DNA minor groove binding agents interfere with topoisomerase II mediated lesions induced by epipodophyllotoxin derivative VM-26 and acridine derivative m-AMSA in nuclei from L1210 cells

This study demonstrated that agents capable of interacting with the minor groove in nuclear DNA interfere with topoisomerase II mediated effects of antitumor drugs such as VM-26 and m-AMSA. Distamycin, Hoechst 33258, and DAPI were used as agents capable of AT-specific binding in the minor groove of DNA while producing no profound long-range distortion of DNA structure. In intact nuclei from L1210 cells, these minor groove binders inhibited the induction of topoisomerase II mediated DNA damage (DNA-protein cross-links and DNA double-strand breaks) by VM-26 and m-AMSA. The inhibitory effects of distamycin reflected prevention of formation of new lesions but not reversal of preexisting damage. The minor groove binders did not differentiate between lesions induced by an intercalator, m-AMSA, or by a DNA-nonbinding drug, VM-26. All three groove binders inhibited DNA breaks more strongly than DNA-protein cross-links. The inhibitory potency correlated with the size of minor groove binders and the size of their DNA-binding sites: distamycin (5 bp) greater than Hoechst 33258 (4 bp) greater than DAPI (3 bp). The results showed that DNA minor groove binders are a new type of modulators of the action of topoisomerase II targeted drugs.     

Region-specific DNA damage by AT-specific DNA-reactive drugs is predicted by drug binding specificity

Bizelesin and adozelesin are DNA-reactive antitumor drugs that alkylate adenines at the 3' ends of their preferred binding sites [5'T(A/T)(4)A3'and 5'(A/T)(3)(-4)A3', respectively]. We used these drugs to examine the determinants for region-specific damage of human genomic DNA. The distribution of bizelesin binding motifs in several regions analyzed "in silico" correlated well with the experimentally determined lesions in these regions assessed by quantitative polymerase chain reaction (QPCR) stop assay. In contrast to the typically low motif density, clusters of potential bizelesin binding sites were found in the matrix-associated regions (MAR domains) of the c-myc and apolipoprotein B (apoB) genes. Accordingly, lesions induced by bizelesin in these domains (2.13 and 7.06 lesions kbp(-1) microM(-1), respectively) markedly exceeded lesions in bulk DNA (0.87 lesions kbp(-1) microM(-1)) or in regions with typically low motif density (e.g., 0.75 and 0.87 lesions kbp(-1) microM(-1) in a beta-globin gene and c-myc origin of replication regions, respectively). Consistent with the more frequent, less localized adozelesin motif, actual lesions induced by adozelesin exceeded by severalfold lesions by bizelesin in four selected regions (within the c-myc and HPRT loci). Whereas adozelesin is likely to affect similar regions as bizelesin, adozelesin's more promiscuous binding probably compromises its relative specificity for such targets. In contrast, findings for bizelesin provide for the first time a proof of principle that a small molecular weight drug can preferentially damage specific regions in cellular DNA. Targeting of critical repetitive sequences, such as AT-rich MAR domains, which allow for clustering of drug binding motif, can be the paradigm for region specificity of small molecular weight agents.     

The effect of topoisomerase inhibitors on the expression of differentiation markers and cell cycle progression in human K-562 leukemia cells.

Treatment of human K-562-J leukemia cells for 1 h with the topoisomerase II-reactive drugs VP-16, VM-26, or mAMSA resulted in a dose-dependent inhibition of proliferation and in an increase in the percentage of cells staining positive for hemoglobin, a marker of erythroid differentiation. Staining for hemoglobin of up to about 60% of the cells was observed at 20 microM VP-16, 1 microM VM-26, and 8 microM mAMSA. Such treatment also caused a G2/M arrest in the cell cycle. Incubation of the cells with radiolabeled VP-16 indicated that the induced erythroid differentiation was not due to continuous cell exposure to a residual amount of the drug. VP-16-induced erythroid differentiation was also not affected by DNA, RNA, or protein synthesis inhibitors. Differentiation induction and the G2/M arrest evoked by VP-16, VM-26, and mAMSA were, however, reduced in the presence of novobiocin. Our results indicate that topo-reactive drugs that cause G2/M arrest in the K-562-J cell cycle can induce in these cells erythroid differentiation after a short and irreversible interaction with their target molecule(s).     

Altered catalytic activity of and DNA cleavage by DNA topoisomerase II from human leukemic cells selected for resistance to VM-26

The simultaneous development of resistance to the cytotoxic effects of several classes of natural product anticancer drugs, after exposure to only one of these agents, is referred to as multiple drug resistance (MDR). At least two distinct mechanisms for MDR have been postulated: that associated with P-glycoprotein and that thought to be due to an alteration in DNA topoisomerase II activity (at-MDR). We describe studies with two sublines of human leukemic CCRF-CEM cells approximately 50-fold resistant (CEM/VM-1) and approximately 140-fold resistant (CEM/VM-1-5) to VM-26, a drug known to interfere with DNA topoisomerase II activity. Each of these lines is cross-resistant to other drugs known to affect topoisomerase II but not cross-resistant to vinblastine, an inhibitor of mitotic spindle formation. We found little difference in the amount of immunoreactive DNA topoisomerase II in 1.0 M NaCl nuclear extracts of the two resistant and parental cell lines. However, topoisomerase II in nuclear extracts of the resistant sublines is altered in both catalytic activity (unknotting) of and DNA cleavage by this enzyme. Also, the rate at which catenation occurs is 20-30-fold slower with the CEM/VM-1-5 preparations. The effect of VM-26 on both strand passing and DNA cleavage is inversely related to the degree of primary resistance of each cell line. Our data support the hypothesis that at-MDR is due to an alteration in topoisomerase II or in a factor modulating its activity.     

Decreased nuclear matrix DNA topoisomerase II in human leukemia cells resistant to VM-26 and m-AMSA

CEM leukemia cells selected for resistance to VM-26 (CEM/VM-1) are cross-resistant to various other DNA topoisomerase II inhibitors but not to Vinca alkaloids. Since DNA topoisomerase II is a major protein of the nuclear matrix, we asked if alterations in nuclear matrix topoisomerase II might be important in this form of multidrug resistance. Pretreatment of drug-sensitive CEM cells for 2 h with either 5 microM VM-26 or 3 microM m-AMSA reduced the specific activity of newly replicated DNA on the nuclear matrix by 75 and 50%, respectively, relative to that of the bulk DNA. However, neither VM-26 nor m-AMSA affected the relative specific activity of nascent DNA isolated from the nuclear matrices of drug-resistant CEM/VM-1 cells. The decatenating and unknotting activities of DNA topoisomerase II were 6- and 7-fold lower, respectively, in the nuclear matrix preparations from the CEM/VM-1 cells compared to parental CEM cells. Western blot analysis revealed that the amount of immunoreactive topoisomerase II in the nuclear matrices of the CEM/VM-1 cells was decreased 3.2-fold relative to that in CEM cells, but there was no significant difference in the amount of enzyme present in the nonmatrix (1.5 M salt soluble) fractions of nuclei from these cell lines. Increasing the NaCl concentration used in the matrix isolation procedure from 0.2 to 1.8 M resulted in a progressive decrease in the specific activity of topoisomerase II in matrices of CEM/VM-1 but not CEM cells, which suggested that the association of the enzyme with the matrix is altered in the resistant cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cisplatin-evoked DNA fragmentation in normal and cancer cells and its modulation by free radical scavengers and the tyrosine kinase inhibitor STI571

Cis-diamminedichloroplatinum(II) (cisplatin, cis-DDP) is well studied anticancer drug, whose activity can be attributed to its ability to form adducts with DNA, but this drug can also form DNA-damaging free radicals, however this mechanism of cisplatin action is far less explored. Using the comet assay we studied cisplatin-induced DNA damage in the presence of spin traps: DMPO and PBN, Vitamins A, C and E as well as the tyrosine kinases inhibitor STI571 in normal human lymphocytes and leukemic K562 cells. The latter cells express the BCR/ABL fusion protein, which can be a target of the tyrosine kinase inhibitor STI571. A 20 h incubation with cisplatin at 1-10 microM induced DNA cross-links and DNA fragmentation in normal and cancer cells. Cisplatin could induce intra- and interstrand DNA-DNA cross-links as well as DNA-protein cross-links. DNA damage in K562 cells was more pronounced than in normal lymphocytes. In the presence of spin traps and vitamins we noticed a decrease in the DNA fragmentation in both cell types. Co-treatment of the lymphocytes with cisplatin at 10 microM and STI571 at 0.25 microg/ml caused an increase of DNA fragmentation in comparison with DNA fragmentation induced by cisplatin alone. In the case of K562 cells, an increase of DNA fragmentation was observed after treatment with cisplatin at 1 microM. Our results indicate that the free radicals scavengers could decrease DNA fragmentation induced by cisplatin in the normal and cancer cells, but probably they have no effect on DNA cross-linking induced by the drug. The results obtained with the BCR/ABL inhibitor suggest that K562 cells could be more sensitive towards co-treatment of cisplatin and STI571. Our results suggest also that aside from the BCR/ABL other factors such as p53 level, signal transduction pathways and DNA repair processes can be responsible for the increased sensitivity of K562 cells to cisplatin compared with normal lymphocytes.     

DNA topoisomerase II is required for formation of mitotic chromosomes in Chinese hamster ovary cells: studies using the inhibitor 4'-demethylepipodophyllotoxin 9-(4,6-O-thenylidene-beta-D-glucopyranoside)

To study the biochemical processes which DNA topoisomerase II carries out in mammalian cells, which have not been identified, we have examined the effects on chromosome replication in Chinese hamster ovary cells of an agent which traps molecules of topoisomerase II when they are covalently integrated into DNA during their reaction. This agent, 4'-demethylepipodophyllotoxin 9-(4,6-O-thenylidene-beta-D-glucopyranoside) (VM-26), targets this enzyme specifically according to a compelling body of evidence. Using synchronously growing cells, we found that VM-26 at a cytotoxic concentration (0.08 microM) did not affect DNA replication during the S phase. The formation of mitotic chromosomes was delayed by 4 h, and its rate was reduced thereafter, causing a delay in mitosis of greater than 14 h in 65% of the cells; in some cells, the chromatin was aberrantly condensed, forming diffuse chromosomes or particles. Chromosome formation was completely inhibited at 0.32 microM VM-26. DNA fragments derived from topoisomerase II molecules covalently integrated in DNA and trapped by VM-26 were detected by FIGE analysis in the G2 period, but not during the S phase. The delay of chromosome formation appeared to be caused by two factors: first, a delay in the completion of DNA replication, because progress of some cells to mitosis after removal of VM-26 was prevented by aphidicolin, an inhibitor of DNA polymerases alpha and delta; and second, a delay of chromosome formation in cells which had apparently completed DNA replication. The observations reported here show that topoisomerase II carries out reactions which are essential for formation of mitotic chromosomes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Protective action of vitamin C against DNA damage induced by selenium-cisplatin conjugate.

Genotoxicity of anticancer drugs is of a special interest due to the risk of inducing secondary malignancies. Vitamin C (ascorbic acid) is a recognized antioxidant and, since human diet can be easily supplemented with vitamin C, it seems reasonable to check whether it can protect against DNA-damaging effects of antitumor drugs. In the present work the ability of vitamin C to modulate cytotoxic and genotoxic effects of a cisplatin analog, conjugate (NH3)2Pt(SeO3), in terms of cell viability, DNA damage and repair in human lymphocytes was examined using the trypan blue exclusion test and the alkaline comet assay, respectively. The conjugate evoked a concentration-dependent decrease in the cell viability, reaching nearly 50% at 250 microM. (NH3)2Pt(SeO3) at 1, 10 and 30 microM caused DNA strand breaks, measured as the increase in the comet tail moment of the lymphocytes. The treated cells were able to recover within a 30-min incubation in a drug-free medium at 37 degrees C. Vitamin C at 10 and 50 microM diminished the extent of DNA damage evoked by (NH3)2Pt(SeO3) but had no effect on the kinetics of DNA repair. The vitamin did not directly inactivate the conjugate. Lymphocytes treated with endonuclease III, which recognises oxidised pyrimidines, displayed a greater tail moment than those untreated with the enzyme, suggesting that the damages induced by the drug have, at least in part, an oxidative origin. Vitamin C can be considered a potential protective agent against side effects of antitumor drugs, but further research with both normal and cancer cells are needed to clarify this point.     

The interaction of peptide-tethered platinum(II) complexes with DNA

The sequence specificity and intensity of DNA damage induced by six peptide-tethered platinum complexes was compared to cisplatin and Pt(en)Cl(2). DNA damage was investigated in pUC19 plasmid and in intact HeLa cells, and quantitatively analyzed using a Taq DNA polymerase/linear amplification assay. The DNA sequence specificity of the peptide-platinum compounds was found to be very similar to cisplatin and Pt(en)Cl(2), with runs of consecutive guanines being the most intensely damaged sites. The observed reactivity of the peptide-platinum complexes towards plasmid DNA was lower compared to cisplatin and Pt(en)Cl(2), with the glycine-tethered complex 3 and the phenylalanine-tethered complex 4 producing the highest relative damage intensity, followed by (in decreasing order) lysine-tethered (5), arginine-tethered (6), serine-tethered (7) and glutamate-tethered (8). The reactivity of the peptide-platinum complexes towards cellular DNA was also lower compared to cisplatin and Pt(en)Cl(2). For most investigated complexes, the relative damage intensities were found to be similar in cells compared to plasmid DNA, but were greatly reduced for 3 and 4. The lysine-tethered 5 complex produced the highest DNA damage intensity in cells followed by (in decreasing order) 6, 7, 3, 4 and 8.     

In vivo stimulation by antitumor drugs of the topoisomerase II induced cleavage sites in c-myc protooncogene

Several antitumor drugs including DNA intercalative and non intercalative agents induce in vitro and in vivo double-stranded DNA breaks by stabilization of a topoisomerase II-DNA complex. In order to locate cleavage sites in an actively transcribed oncogene, N417 cells, originating from a human small cell lung carcinoma and containing 45-50 copies of c-myc oncogene, were treated with mAMSA, 9 hydroxyellipticine and VM 26. The presence of DNA lesions in c-myc was investigated by Southern blot hybridization with a human c-myc probe. In addition to normal bands, DNA patterns of drug treated-cells revealed the presence of new bands most likely corresponding to topoisomerase II-mediated cleavage as these bands were not found in untreated control DNA and in DNA treated with oAMSA, a biologically inactive stereoisomer of mAMSA. Major cleavage sites induced by drugs in the N417 cell c-myc locus were located in the 5' end of the c-myc exon 1 closely to some DNAse I hypersensitive sites which are assumed to reflect an activity of the gene. Therefore our data suggest that TopoII-mediated drug activity correlates with gene activity.     

Topoisomerase-II-mediated lesions in nascent DNA: comparison of the effects of epipodophyllotoxin derivatives, VM-26 and VP-16, and 9-anilinoacridine derivatives, m-AMSA and o-AMSA

This study compares the effects of the epipodophyllotoxin derivatives, VM-26 and VP-16, and the 9-anilinoacridine derivatives, m-AMSA and o-AMSA, on nascent and mature DNA. Two types of lesion which are putatively mediated by topoisomerase II, DNA-protein crosslinks and DNA double-strand breaks, were analyzed in drug-treated nuclei from 3H/14C labelled L1210 cells. Potassium/dodecyl sulfate precipitation assay was used to assess DNA-protein crosslinks in mature and nascent (1 min old) DNA. Both epipodophyllotoxins and m-AMSA showed a strong preference for nascent DNA. DNA double-strand cleavage induced by VM-26 and m-AMSA also showed a preference for nascent DNA as indicated by neutral elution technique. Sedimentation on neutral sucrose gradients revealed that these drugs generated highly degraded fragments (under 30 S) in nascent DNA substantially faster than in mature DNA. Lesions in nascent DNA were diminished substantially by the omission of ATP or the addition of novobiocin. The ability to induce lesions in nascent DNA correlates with cytotoxic potency of the agents studied. The results suggest that replicating DNA may constitute a preferential target for antitopoisomerase II drugs.     

Ouabain,a Cardiac Glycoside,Inhibits the Fanconi Anemia/BRCA Pathway Activated by DNA Interstrand Cross-Linking Agents

Modulation of the DNA repair pathway is an emerging target for the development of anticancer drugs. DNA interstrand cross-links (ICLs), one of the most severe forms of DNA damage caused by anticancer drugs such as cisplatin and mitomycin C (MMC), activates the Fanconi anemia (FA)/BRCA DNA repair pathway. Inhibition of the FA/BRCA pathway can enhance the cytotoxic effects of ICL-inducing anticancer drugs and can reduce anticancer drug resistance. To find FA/BRCA pathway inhibitory small molecules, we established a cell-based high-content screening method for quantitating the activation of the FA/BRCA pathway by measuring FANCD2 foci on DNA lesions and then applied our method to chemical screening. Using commercial LOPAC1280 chemical library screening, ouabain was identified as a competent FA/BRCA pathway inhibitory compound. Ouabain, a member of the cardiac glycoside family, binds to and inhibits Na⁺/K⁺-ATPase and has been used to treat heart disease for many years. We observed that ouabain, as well as other cardiac glycoside family members―digitoxin and digoxin―down-regulated FANCD2 and FANCI mRNA levels, reduced monoubiquitination of FANCD2, inhibited FANCD2 foci formation on DNA lesions, and abrogated cell cycle arrest induced by MMC treatment. These inhibitory activities of ouabain required p38 MAPK and were independent of cellular Ca²⁺ ion increase or the drug uptake-inhibition effect of ouabain. Furthermore, we found that ouabain potentiated the cytotoxic effects of MMC in tumor cells. Taken together, we identified an additional effect of ouabain as a FA/BRCA pathway-inhibiting chemosensitization compound. The results of this study suggest that ouabain may serve as a chemosensitizer to ICL-inducing anticancer drugs.     

Transfer RNA bindings to antitumor estradiol-platinum(II) hybrid and cisplatin

The anticancer platinum (Pt) drugs exert their antitumor activity by direct or indirect Pt-DNA binding. It has been shown that Pt drugs can induce major DNA damage and minor RNA damage during cancer treatment. A recent report showed that a new anticancer estradiol-Pt(II) hybrid molecule (CD-37) binds DNA bases indirectly, while being more effective than cis-diaminedichloroplatinum(II) (cisplatin) against several types of cancer. In this report, we examine the bindings of CD-37 and cisplatin drugs with transfer RNA (tRNA) in vitro and compare the results to those of the corresponding Pt-DNA complexes. Solutions containing various CD-37 or cisplatin concentrations were reacted with tRNA at physiological pH. Using Fourier transform infrared (FTIR), UV-visible, and circular dichroism spectroscopic methods, the drug binding mode, the binding constant, and RNA structural variations are determined for Pt-tRNA complexes in aqueous solution. Structural analysis showed direct binding of cisplatin drug to guanine and adenine N7 sites, while both direct and indirect interactions of CD-37 with tRNA bases and the backbone phosphate group were observed. The overall binding constants estimated were K(CD-37) = 2.77 (+/-0.90) x 10(4) M(1) and K(cisplatin) = 1.72 (+/-0.50) x 10(4) M(1). Major aggregation of tRNA occurs at high CD-37 concentrations, while RNA remains in the A-family structure.     

Different recognition of DNA modified by aatitumor cisplatin and its clinically ineffective trans isomer by tumor suppressor protein p53

The p53 gene encodes a nuclear phosphoprotein that is biologically activated in response to genotoxic stresses including treatment with anticancer platinum drugs. The DNA binding activity of p53 protein is crucial for its tumor suppressor function. DNA interactions of active wild-type human p53 protein with DNA fragments and oligodeoxyribonucleotide duplexes modified by antitumor cisplatin and its clinically ineffective trans isomer (transplatin) were investigated by using a gel mobility shift assay. It was found that DNA adducts of cisplatin reduced binding affinity of the consensus DNA sequence to p53, whereas transplatin adducts did not. This result was interpreted to mean that the precise steric fit required for the formation and stability of the tetrameric complex of p53 with the consensus sequence cannot be attained, as a consequence of severe conformational perturbations induced in DNA by cisplatin adducts. The results also demonstrate an increase of the binding affinity of p53 to DNA lacking the consensus sequence and modified by cisplatin but not by transplatin. In addition, only major 1,2-GG intrastrand cross-links of cisplatin are responsible for this enhanced binding affinity of p53. The data base on structures of various DNA adducts of cisplatin and transplatin reveals distinctive structural features of 1,2-intrastrand cross-links of cisplatin, suggesting a unique role for this adduct in the binding of p53 to DNA lacking the consensus sequence. The results support the hypothesis that the mechanism of antitumor activity of cisplatin may also be associated with its efficiency to affect the binding affinity of platinated DNA to active p53 protein.     

A new compound, withangulatin A, promotes type II DNA topoisomerase-mediated DNA damage

Withangulatin A, a new compound with a known chemical structure and from the antitumor Chinese herb Physalis angulata L, was found to act on topoisomerase II to induce topoisomerase II-mediated DNA damage in vitro. It has two effective dosage ranges of approximate 0.5 and 20 microM, with about one-third the activity of 20 microM VM-26.     

Analysis of DNA damage and repair in murine leukemia L1210 cells using a quantitative polymerase chain reaction assay.

The polymerase chain reaction (PCR) represents an alternative to the current methods for investigating DNA damage and repair in specific genomic segments. In theory, any DNA lesion which blocks Taq polymerase can be measured by this assay. We used quantitative PCR (QPCR) to determine the lesion frequencies produced by cisplatin and ultraviolet light (UV) in a 2.3 kilobase (kb) segment of mitochondrial DNA and a 2.6 kb segment of the DHFR gene in mouse leukemia L1210 cells. The frequency of UV-induced lesions increased linearly with dose, and was 0.58 lesions/10 kb/10 J/m2 in the mitochondrial DNA, and 0.37 lesions/10 kb/10 J/m2 in the DHFR gene. With cisplatin, the lesion frequency also increased linearly with dose, and was 0.17 lesions/10 kb/10 microM in the DHFR gene, and 0.07 lesions/10 kb/10 microM in mitochondrial DNA. This result is contrary to that of Murata et al., 1990 (1), in which mitochondrial DNA received greater cisplatin damage than did nuclear DNA. Using PCR to measure the repair of UV-induced lesions in the DHFR gene segment, we observed that less than 10% of the lesions were removed by 4 h, but over 70% of the lesions were removed by 8 h. Repair of 43% of UV-induced lesions in mitochondrial DNA was also observed during a 24 h period.     

Activity of the c-myc Replicator at an Ectopic Chromosomal Location

DNA replication starts at multiple discrete sites across the human chromosomal c-myc region, including two or more sites within 2.4 kb upstream of the c-myc gene. The corresponding 2.4-kb c-myc origin fragment confers autonomously replicating sequence (ARS) activity on plasmids, which specifically initiate replication in the origin fragment in vitro and in vivo. To test whether the region that displays plasmid replicator activity also acts as a chromosomal replicator, HeLa cell sublines that each contain a single copy of the Saccharomyces cerevisiae FLP recombinase target (FRT) sequence flanked by selectable markers were constructed. A clonal line containing a single unrearranged copy of the transduced c-myc origin was produced by cotransfecting a donor plasmid containing the 2.4-kb c-myc origin fragment and FRT, along with a plasmid expressing the yeast FLP recombinase, into cells containing a chromosomal FRT acceptor site. The amount of short nascent DNA strands at the chromosomal acceptor site was quantitated before and after targeted integration of the origin fragment. Competitive PCR quantitation showed that the c-myc origin construct substantially increased the amount of nascent DNA relative to that at the unoccupied acceptor site and to that after the insertion of non-myc DNA. The abundance of nascent strands was greatest close to the c-myc insert of the integrated donor plasmid, and significant increases in nascent strand abundance were observed at sites flanking the insertion. These results provide biochemical and genetic evidence for the existence of chromosomal replicators in metazoan cells and are consistent with the presence of chromosomal replicator activity in the 2.4-kb region of c-myc origin DNA.