An investigation of the sequence-specific interaction of cis-diamminedichloroplatinum(II) and four analogues, including two acridine-tethered complexes, with DNA inside human cells.

The sequence specificity of DNA damage caused by cis-diamminedichloroplatinum(II) (cisplatin) and four analogues in human (HeLa) cells was studied using Taq DNA polymerase and a linear amplification system. The primer extension is inhibited by the drug-DNA adducts, and hence the sites of these lesions can be analyzed on DNA sequencing gels. The repetitive alphoid DNA was used as the target DNA in human cells. A comparison was made between adduct formation in human cells and in purified DNA. The sequence-specific position and relative intensity of damage was similar in both systems for cisplatin, dichloro(ethylenediammine)platinum(II) (PtenCl2), and N-[3-N-(ethylenediamino)propyl]acridine-4-carboxamidedichloropl atinum(II) (4AcC3PtenCl2). However, no DNA damage could be detected in cells for trans-diamminedichloroplatinum(II) (transPt) or N-[3-N-(ethylenediamino)propyl]acridine-2-carboxamide-dichloroplat inum(II) (2AcC3PtenCl2) despite the ability of these latter analogues to damage purified DNA. Cisplatin, PtenCl2, and 4AcC3PtenCl2, which significantly damaged DNA inside cells, also show antitumor activity in mouse models. However, transPt and 2AcC3PtenCl2, which did not detectably damage DNA inside cells, did not show such antitumor activity. This correlation between intracellular DNA damaging ability and in vivo antitumor activity indicates the potential use of the human cells/Taq DNA polymerase/linear amplification technique as a convenient method for screening new cisplatin analogues for useful chemotherapeutic activity.     

The interaction of DNA-targeted 9-aminoacridine-4-carboxamide platinum complexes with DNA in intact human cells

As part of an ongoing drug development programme, this paper describes the sequence specificity and time course of DNA adduct formation for a series of novel DNA-targeted analogues of cis-diaminedichloroplatinum(II) (cisplatin) (9-aminoacridine-4-carboxamide Pt complexes) in intact HeLa cells. The sequence specificity of DNA damage caused by cisplatin and analogues in human (HeLa) cells was studied using Taq DNA polymerase and a linear amplification/polymerase stop assay. Primer extension is inhibited by a Pt-DNA adduct, and hence the sites of these lesions can be analysed on DNA sequencing gels. The repetitive alphoid DNA sequence was used as the target DNA in human cells. The 9-aminoacridine-4-carboxamide Pt complexes exhibited a markedly different sequence specificity relative to cisplatin and other analogues. The sequence specificity of the 9-aminoacridine-4-carboxamide Pt complexes is shifted away from a preference for runs of guanines. The 9-aminoacridine-4-carboxamide Pt complexes have an enhanced preference for GA dinucleotides. This is the first occasion that an altered DNA sequence specificity has been demonstrated for a cisplatin analogue in human cells. A time course of DNA damage revealed that the DNA-targeted Pt complexes, consisting of four 9-aminoacridine-4-carboxamide Pt complexes and one acridine-4-carboxamide Pt complex, damaged DNA more rapidly compared to cisplatin and non-targeted analogues. A comparison of the time taken to reach half the maximum relative intensity indicated that the DNA-targeted Pt complexes reacted approximately 4-fold faster than cisplatin and the non-targeted analogues.     

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.     

The interaction of DNA-targeted platinum phenanthridinium complexes with DNA.

Cisplatin analogues were synthesised that consisted of platinum(II) diamine complexes tethered via a polymethylene chain ( n = 3, 5, 8 and 10) to a phenanthridinium cation. Both chloro and iodo leaving groups were examined. DNA adduct formation was quantitatively analysed using a linear amplification system with the plasmid pGEM-3Zf(+). This system utilised Taq DNA polymerase to extend from an oligonucleotide primer to the damage site. This damage site inhibited the extension of the DNA polymerase. The products were electrophoresed on a DNA sequencing gel enabling adduct formation to be determined at base pair resolution. The damage intensity at each site was determined by densitometry. The platinum phenanthridinium complexes were shown to damage DNA at shorter incubation times than cisplatin. To produce similar levels of damage, an 18 h incubation was required for cisplatin compared to 30 min for the n = 3 platinum phenanthridinium complexes; this indicates that the intercalating chromophore causes a large increase in the rate of platination. A reaction mechanism involving direct displacement of the chloride by the N-7 of guanine may account for the rate increase. These results indicate that further development of these compounds could lead to more effective cancer chemotherapeutic agents.     

Plasmodium falciparum: DNA sequence specificity of cisplatin and cisplatin analogues

In this paper, we provided evidence that cisplatin is able to form adducts with cellular DNA in Plasmodium falciparum. The DNA sequence specificity of cisplatin adduct formation was determined in trophozoite-enriched P. falciparum cells and this paper represents the first occasion that the sequence specificity of cisplatin DNA damage has been observed in malaria cells. Utilising a sub-telomeric, 692 bp repeat sequence in the P. falciparum genome, we were able to investigate the DNA adducts formed by cisplatin and five analogues. A run of eight consecutive guanines was the most prominent site of DNA damage in the malarial cells. This study suggests that the mechanism of P. falciparum cell death caused by cisplatin involves damage to DNA and hence inhibition of DNA replication and cell division.     

The interaction of cisplatin and analogues with DNA in reconstituted chromatin

The influence of chromatin structure on cis-diamminedichloroplatinum(II) (cisplatin) DNA damage was investigated in a reconstituted nucleosome system. Nucleosomes were reconstituted on the somatic 5S rRNA gene from Xenopus borealis using the octamer transfer method of reconstitution. Footprinting techniques, utilising bleomycin and DNase I as the damaging agents, were employed to establish the precise location of positioned nucleosomes with respect to the DNA sequence. Reconstituted nucleosomal DNA was treated with cisplatin and drug-induced DNA adduct formation was quantitatively analysed with a polymerase stop assay using Taq DNA polymerase. A densitometric comparison of the relative damage band intensities between purified and reconstituted DNA revealed regions of relative protection corresponding to the sites of the positioned nucleosome cores. This indicated that the preferred site of cisplatin DNA binding was in the linker region of the nucleosome. Statistical analysis showed significant protection from cisplatin DNA damage in the core region of the nucleosome. Three cisplatin analogues were also investigated in this reconstituted nucleosome system. These analogues, cis-diammine(1,1-cyclobutanedicarboxylato)platinum(II) (carboplatin), cis-dichlorobis(cyclohexylamine)platinum(II) (cis-[PtCl(2)(C(6)H(11)NH(2))(2)]) and dichloro(N-[3-[(2-aminoethyl)-amino]propyl]acridine-4-carboxamide)platinum(II) (ac-PtenCl(2)(n3)), were also found to target the linker region of the nucleosome. The latter DNA-targeted acridine-platinum complex gave rise to the most predominant footprints of all the Pt compounds tested.     

The interaction of cisplatin with a human telomeric DNA sequence containing seventeen tandem repeats

The anti-tumour drug, cisplatin, preferentially forms adducts at G-rich DNA sequences. Telomeres are found at the ends of chromosomes and, in humans, contain the repeated DNA sequence (GGGTTA)_n that is expected to be targeted by cisplatin. Using a plasmid clone with 17 tandem telomeric repeats, (GGGTTA)₁₇, the DNA sequence specificity of cisplatin was investigated utilising the linear amplification procedure that pin-pointed the precise sites of cisplatin adduct formation. This procedure used a fluorescently labelled primer and capillary electrophoresis with laser-induced fluorescence detection to determine the DNA sequence specificity of cisplatin. This technique provided a very accurate analysis of cisplatin-DNA adduct formation in a long telomeric repeat DNA sequence. The DNA sequence specificity of cisplatin in a long telomeric tandem repeat has not been previously reported. The results indicated that the 3′-end of the G-rich strand of the telomeric repeat was preferentially damaged by cisplatin and this suggests that the telomeric DNA repeat has an unusual conformation.     

Conversion of monofunctional DNA adducts of cis-diamminedichloroplatinum (II) to bifunctional lesions. Effect on the in vitro replication of single-stranded DNA by Escherichia coli DNA polymerase I and eukaryotic DNA polymerases alpha

Reaction of cis-diamminedichloroplatinum (II) with single-stranded M13 phage DNA in vitro produced monofunctional platinum-DNA adducts on guanine and bifunctional lesions with either two guanine bases (GG) or one adenine and one guanine (AG). When DNA containing a majority of monofunctional platinum-DNA lesions was dialyzed against 10 mM NaCIO4 at 37 degrees C, conversion of monoadducts to bifunctional lesions was observed. We examined the effect of post-treatment formation of bifunctional lesions on DNA synthesis by Escherichia coli DNA polymerase I and highly purified eukaryotic DNA polymerase alpha from Drosophila melanogaster and calf thymus. Arrest sites on the platinated template were determined by polyacrylamide gel electrophoresis. Monofunctional lesions did not appear to block DNA synthesis. Inhibition of replication increased as bifunctional platinum-DNA lesions formed during post-treatment incubation; GG adducts inhibited replication more than AG. These results suggest that bifunctional GG platinum-DNA adducts may be the major toxic damage of cisplatin.     

DNA damage by anti-cancer agents resolved at the nucleotide level of a single copy gene: evidence for a novel binding site for cisplatin in cells.

A new PCR based technique has been developed to investigate the sequence selectivity of adduct formation by DNA damaging agents in a single copy gene in isolated genomic DNA or in drug treated cells. Single-strand ligation PCR (sslig-PCR) demonstrated that cisplatin and nitrogen mustards reacted with guanine in an N-ras fragment with varying sequence specificity similar to that observed previously in plasmid DNA. In cisplatin-treated cells sslig-PCR demonstrated all the adducts found in isolated DNA and with the same sequence selectivity showing a preference for GG and AG sites. However, in cells an additional site of DNA binding of cisplatin was observed at the two occurrences of the sequence 5'-TACT-3' on the transcribed and non-transcribed strands. This sequence is not a recognised target for cisplatin and represents a novel adduct formed in cells.     

Formation of cis-diamminedichloroplatinum(II) 1,2-intrastrand cross-links on DNA is flanking-sequence independent

Mapping of cis-diamminedichloroplatinum(II) (cis-DDP, cisplatin) DNA adducts over >3000 nucleotides was carried out using a replication blockage assay. The sites of inhibition of modified T4 DNA polymerase, also referred to as stop sites, were analyzed to determine the effects of local sequence context on the distribution of intrastrand cisplatin cross-links. In a 3120 base fragment from replicative form M13mp18 DNA containing 24.6% guanine, 25.5% thymine, 26.9% adenine and 23.0% cytosine, 166 individual stop sites were observed at a bound platinum/nucleotide ratio of 1-2 per thousand. The majority of stop sites (90%) occurred at G(n>2) sequences and the remainder were located at sites containing an AG dinucleotide. For all of the GG sites present in the mapped sequences, including those with Gn(>)2, 89% blocked replication, whereas for the AG sites only 17% blocked replication. These blockage sites were independent of flanking nucleotides in a sequence of N(1)G*G*N(2) where N(1), N(2) = A, C, G, T and G*G* indicates a 1,2-intrastrand platinum cross-link. The absence of long-range sequence dependence was confirmed by monitoring the reaction of cisplatin with a plasmid containing an 800 bp insert of the human telomere repeat sequence (TTAGGG)(n). Platination reactions monitored at several formal platinum/nucleotide ratios or as a function of time reveal that the telomere insert was not preferentially damaged by cisplatin. Both replication blockage and telomere-insert plasmid platination experiments indicate that cisplatin 1,2-intrastrand adducts do not form preferentially at G-rich sequences in vitro.     

DNA sequence-specific adenine alkylation by the novel antitumor drug tallimustine (FCE 24517), a benzoyl nitrogen mustard derivative of distamycin.

FCE 24517, a novel distamycin derivative possessing potent antitumor activity, is under initial clinical investigation in Europe. In spite of the presence of a benzoyl nitrogen mustard group this compound fails to alkylate the N7 position of guanine, the major site of alkylation by conventional nitrogen mustards. Characterisation of DNA-drug adducts revealed only a very low level of adenine adduct formation. Using a modified Maxam-Gilbert sequencing method the consensus sequence for FCE 24517-adenine adduct formation was found to be 5'-TTTTGA-3'. A single base modification in the hexamer completely abolishes the alkylation of adenine. Using a Taq polymerase stop assay alkylations were confirmed at the A present in the hexamer TTTTGA and, in addition, in one out of three TTTTAA sequences present in the plasmid utilized. The sequence specificity of alkylation by FCE 24517 is therefore the most striking yet observed for an alkylating agent of small molecular weight.     

DNA adducts of the enantiomers of the Pt(II) complexes of the ahaz ligand (ahaz=3-aminohexahydroazepine) and recognition of these adducts by HMG domain proteins

The bending, unwinding, and structural changes in DNA caused by the binding of each of the enantiomers of the platinum(II) complexes of the ahaz ligand (R- and S-[PtCl(2)(ahaz)], ahaz=3-aminohexahydroazepine) have been studied using 20-23 bp oligonucleotides containing TGGT and CGGA-binding sites as has the recognition of the adducts by HMG domain proteins. The domain A of HMGB1 (HMGB1a protein) binds to the adduct formed by the R enantiomer at the CGGA sequence with a similar high affinity as it does to the adduct of antitumor cisplatin, and to the adduct formed by the S enantiomer with a slightly lower affinity. In contrast, HMGB1a binds much more weakly to the ahaz adducts than to the cisplatin adducts formed at the TGGT sequence, with the binding to the adduct formed by the R enantiomer being weakest. Each enantiomer and cisplatin cause unwinding of both sequences that is in the narrow range, 19-22 degrees. There are modest but significant differences in the degree of bending induced, with the S enantiomer causing the least bending, cisplatin intermediate, and the R enantiomer the most. Molecular modeling of the {Pt(ahaz)}/GG adducts in 8-bp models reveals significant differences in the local distortion at the GG-binding sites depending on the flanking bases and shows that interactions between the thymine methyl groups and the ahaz ligand are likely to inhibit bending of the TGGT sequence.     

Double base lesions of DNA by a metabolite of carcinogenic benzo[a]pyrene.

Carcinogenic benzo[a]pyrene (BP) is generally considered to show genotoxicity by forming DNA adducts of its metabolite, BP-7,8-diol-9,10-epoxide. We investigated oxidative DNA damage and its sequence specificity induced by BP-7,8-dione, another metabolite of BP, using (32)P-5'-end-labeled DNA. Formamidopyrimidine-DNA glycosylase treatment induced cleavage sites mainly at G residues of 5'-TG-3' sequence and at poly(C) sequences, in DNA incubated with BP-7,8-dione in the presence of NADH and Cu(II), whereas piperidine treatment induced cleavage sites at T mainly of 5'-TG-3'. BP-7,8-dione strongly damaged the G and C of the ACG sequence complementary to codon 273 of the p53 gene. Catalase and a Cu(I)-specific chelator attenuated the DNA damage, indicating the involvement of H(2)O(2) and Cu(I). BP-7,8-dione with NADH and Cu(II) also increased 8-oxo-7,8-dihydro-2'-deoxyguanosine formation. We conclude that oxidative DNA damage, especially double base lesions, may participate in the expression of carcinogenicity of BP in addition to DNA adduct formation.     

Detection of neocarzinostatin chromophore-deoxyribose adducts as exonuclease-resistant sites in defined-sequence DNA

A 5'-end-labeled DNA restriction fragment was treated with the nonprotein chromophore of neocarzinostatin under anoxia in the presence of dithiothreitol, conditions known to maximize formation of chromophore-deoxyribose adducts. Under conditions where unmodified DNA was digested to completion, chromophore-treated DNA was highly resistant to digestion by exonuclease III plus the 3'----5' exonucleolytic activity of T4 DNA polymerase and partially resistant to digestion by exonuclease III plus snake venom exonuclease. The electrophoretic mobilities of the products of exonucleolytic digestion suggested that (i) digestion by exonuclease III or T4 polymerase terminated one nucleotide before the nucleotide containing the adduct, (ii) the remaining nucleotide directly adjacent to the adduct (3' side) could be removed by snake venom phosphodiesterase, but at a slow rate, (iii) the covalently linked chromophore decreased the electrophoretic mobilities of the digestion products by the equivalent of approximately three nucleotides, and (iv) adducts formed under anaerobic conditions occurred at the same nucleotide positions as the strand breaks formed under aerobic conditions (primarily at T and, to a lesser extent, A residues). The close similarity in sequence specificity of adducts and strand breaks suggests that a common form of nascent DNA damage may be a precursor to both lesions. A chromophore-induced free radical on C-5' of deoxyribose, subject to competitive fixation by addition reactions with either oxygen or chromophore, is the most likely candidate for such a precursor. The base specificity of adduct formation does not reflect the reported base specificity of neocarzinostatin-induced mutagenesis, suggesting that lesions other than adducts may be responsible for at least some neocarzinostatin-induced mutations, particularly those occurring at G X C base pairs.     

Translesion synthesis past platinum DNA adducts by human DNA polymerase mu

DNA polymerase mu (pol mu) is a member of the pol X family of DNA polymerases, and it shares a number of characteristics of both DNA polymerase beta (pol beta) and terminal deoxynucleotidyl transferase (TdT). Because pol beta has been shown to perform translesion DNA synthesis past cisplatin (CP)- and oxaliplatin (OX)-GG adducts, we determined the ability of pol mu to bypass these lesions. Pol mu bypassed CP and OX adducts with an efficiency of 14-35% compared to chain elongation on undamaged DNA, which is second only to pol eta in terms of bypass efficiency. The relative ability of pol mu to bypass CP and OX adducts was dependent on both template structure and sequence context. Since pol mu has been shown to be more efficient on gapped DNA templates than on primed single-stranded DNA templates, we determined the ability of pol mu to bypass Pt-DNA adducts on both primed single-stranded and gapped templates. The bypass of Pt-DNA adducts by pol mu was highly error-prone on all templates, resulting in 2, 3, and 4 nt deletions. We postulate that bypass of Pt-DNA adducts by pol mu may involve looping out the Pt-GG adduct to allow chain elongation downstream of the adduct. This reaction appears to be facilitated by the presence of a downstream "acceptor" and a gap large enough to provide undamaged template DNA for elongation past the adduct, although gapped DNA is clearly not required for bypass.     

A comparison of in vitro platinum-DNA adduct formation between carboplatin and cisplatin

• 1.1. DNA damage induced by carboplatin [cis-diammine-(1,1-cyclobutanedi-carboxylato)platinum(II)] was studied in vitro in comparison with cisplatin [cis-diammine-dichloroplatinum(II)]. The drug-induced DNA damage monitored by conformational change of pUC18 plasmid DNA showed that carboplatin required 10 times higher drug concentration and 7.5 times longer incubation time than those of cisplatin to induce the same degree of conformational change on plasmid DNA.
• 2.2. The carboplatin-induced DNA damage was promoted by the increase of pH of the reaction mixture for platinum-DNA adduct formation.
• 3.3. Sequence gel analysis of carboplatin-damaged DNA indicated that carboplatin attacked preferentially the sequence of GG > AG > GA > GNG in the order, similarly to the case of cisplatin.
• 4.4. DNA adducts formed by carboplatin were analyzed by HPLC after a sequential digestion of carboplatin-treated DNA with deoxyribonuclease I and S1 nuclease. A single peak having the same retention time as that of bifunctional adduct of (dGMP)₂Pt(NH₃)₂ appeared by treating DNA with carboplatin. The adduct was assigned to be d(pGpG) > Pt(NH₃)₂.
• 5.5. These results suggested that carboplatin induces the same platinum-DNA adducts as those induced by cisplatin, and that the difference in efficiency or kinetics of DNA damage between carboplatin and cisplatin is due to difference of aquation rate between them.

     

The DNA sequence selectivity of maltolato-containing cisplatin analogues in purified plasmid DNA and in intact human cells

Cisplatin analogues with an attached DNA binding moiety have a higher affinity for DNA, but often suffer from poor aqueous solubility. In this study we examined the DNA sequence specificity of more soluble cisplatin analogues containing the maltolato leaving group in both purified DNA and in intact human cells. In both environments the DNA sequence specificity of these analogues was very similar to cisplatin. However, in purified DNA a higher concentration of the two maltolato-containing analogues was needed to achieve a similar level of DNA damage as cisplatin. This difference in reactivity was not observed in intact cells as the two maltolato-containing complexes were capable of producing a similar level of damage as cisplatin at comparable concentrations. This was consistent with the IC₅₀ values obtained for both cisplatin and the maltolato compounds which were also similar. This study indicated that maltolato can be utilised as the leaving group to increase the aqueous solubility of cisplatin analogues without reducing their biological activity.     

Thermolabile adenine adducts and A.T base pair substitutions induced by nitrogen mustard analogues in an SV40-based shuttle plasmid.

It was previously shown that the predominant mutations induced by melphalan (L-phenylalanine mustard) in the supF gene of shuttle plasmid pZ189 during replication in human cells are A.T----T.A transversions. In order to determine whether adenine adducts were formed at sequence positions corresponding to these mutations, melphalan-induced thermolabile adducts were mapped in the supF gene by selective depurination followed by strand cleavage in alkali. All A.T base pairs which were frequent sites for melphalan-induced A.T----T.A transversions were also prominent sites for formation of thermolabile adenine adducts. Although no mutations were detected at some prominent adduct sites, there was a significant correlation between adduct sites and mutation sites. While runs of two or more adenines were particularly prominent adduct sites, comparison of results obtained with 3'- and 5'-end-labeled DNA gave no evidence for intrastrand cross-links between adjacent adenines. Chlorambucil, another aromatic nitrogen mustard, showed sequence specificities for both mutagenesis and adenine adduct formation nearly identical to those seen with melphalan. The nonaromatic analogues mechlorethamine and phosphoramide mustard were much less efficient in inducing thermolabile adenine adducts, and mechlorethamine induced significantly fewer transversions at A.T base pairs than chlorambucil or melphalan. Formation of thermolabile adenine adducts by the aromatic nitrogen mustards was markedly reduced by blockage of the minor groove with distamycin, or by prior heat denaturation of the DNA. These results suggest that alkylation occurs primarily at the N-3 rather than N-7 position of adenine, probably as a consequence of the affinity of the aromatic rings of melphalan and chlorambucil for the minor groove.(ABSTRACT TRUNCATED AT 250 WORDS)