Circular dichroism study of the irreversibility of conformational changes induced by polyamine-linked dinuclear platinum compounds

In this work, the reversibility of both the B-->Z and B-->A conformational change in polymer DNA induced by polynuclear platinum compounds was studied. The compounds examined were: [[trans-PtCl(NH(3))(2)](2)[NH(2) (CH(2))(6)NH(2)]](2+) (BBR3005); [[trans-PtCl(NH(3))(2)](2)[mu-spermine-N1,N12]](4+) (BBR3535); [[trans-PtCl(NH(3))(2)](2)[mu-spermidine-N1,N8]](3+) (BBR3571); [[trans-PtCl(NH(3))(2)](2)[mu-BOC-spermidine]](2+) (BBR3537); and [[trans-PtCl(NH(3))(2)](2)[mu-trans-Pt(NH(3))(2)(H(2)N(CH(2))(6)NH(2))(2)]](4+) (BBR3464). The conformational changes were assessed by circular dichroism and the reversibility of the transitions was tested by subsequent titration with the DNA intercalator ethidium bromide (EtBr). Fluorescent quenching was also used to assess the ability of ethidium bromide to intercalate into A and/or Z-DNA induced by the compounds. The results were compared with those produced by the simple hexamminecobalt cation [Co(NH(3))(6)](3+). The data suggest that while conformational changes induced by electrostatic interactions are confirmed to be reversible, covalent binding induces irreversible changes in both the A and Z conformation. The relevance of these changes to the novel biological action of polynuclear platinum compounds is discussed.     

Cooperative effects in long-range 1,4 DNA-DNA interstrand cross-links formed by polynuclear platinum complexes: an unexpected syn orientation of adenine bases outside the binding sites

The novel phase II anticancer drug BBR3464 ([[ trans-PtCl(NH(3))(2)](2)- micro -[ trans-Pt(NH(3))(2)(NH(2)(CH(2))(6)NH(2))(2)]](NO(3))(4)) forms a 1,4-interstrand cross-link adduct with the self-complementary DNA octamer 5'-d(ATG*TACAT)(2)-3', with the two platinum atoms coordinated in the major groove at the N7 positions of guanines that are four base pairs apart on opposite DNA strands. The "central" tetraamine linker [ trans-H(2)N(CH(2))(6)NH(2)Pt(NH(3))(2)NH(2)(CH(2))(6)NH(2)] was located in or close to the minor groove. The adduct was characterized and analyzed by MS, UV and NMR spectroscopy. NMR analysis of the adduct shows strong H8/H1' intraresidue crosspeaks observed for the A1 and A7 resonances, consistent with a syn conformation for these bases which is usually not observed for adenine residues and bases not directly involved in the cross-link in oligonucleotides. The strong intraresidue H8/H1' crosspeak is also observed for G3. Examination of the structure thus reveals unusual cooperative effects unique to this class of anticancer drugs and is the first demonstration of cooperative effects in solution for an anticancer drug. The significant characteristic of the structure is the lack of severe DNA distortion such as a kink, directed bend or significant unwinding of the helices which are characteristic for DNA adducts of mononuclear complexes. This may contribute to the lack of protein recognition of the cross-link by HMG-domain proteins, a biological consequence significantly different from that of mononuclear complexes such as cisplatin. Since DNA is the principal target in vivo for these Pt cross-linking agents, the unique structural perturbations induced by BBR3464 cross-links are likely related to its increased cytotoxicity and antitumor activity as compared to cisplatin ( cis-DDP).     

Effect of the geometry of the central coordination sphere in antitumor trinuclear platinum complexes on DNA binding

Polynuclear platinum compounds comprise a unique class of anticancer agents with chemical and biological properties different from mononuclear platinum drugs. The lead compound of this class is bifunctional trinuclear platinum complex [[trans-PtCl(NH(3))(2)](2)mu-trans-Pt(NH(3))(2)[H(2)N(CH(2))(6)NH(2)](2)](4+) (1,0,1/t,t,t, BBR 3464). Interestingly, the geometry of the coordination spheres in this compound affects potency. For example, the central cis unit of [[trans-PtCl(NH(3))(2)](2)mu-cis-Pt(NH(3))(2)[H(2)N(CH(2))(6)NH(2)](2)](4+) (1,0,1/t,c,t, BBR 3499) results in substantially reduced cytotoxicity. It has been shown that the interactions of polynuclear platinum drugs with target DNA are distinct from the mononuclear-based cisplatin family. In the present work the DNA binding of 1,0,1/t,c,t in cell-free media was examined by the methods of molecular biophysics and compared to the binding of 1,0,1/t,t,t. The binding of 1,0,1/t,c,t is slower and less sequence specific. 1,0,1/t,c,t also forms on DNA long-range delocalized intrastrand and interstrand cross-links similarly as 1,0,1/t,t,t, although the frequency of interstrand adducts is markedly enhanced. Importantly, the adducts of 1,0,1/t,c,t distort DNA conformation and are repaired by cell-free extracts considerably more than the adducts of 1,0,1/t,t,t. It has been suggested that the unique properties of long-range interstrand cross-links of bifunctional trinuclear platinum complexes and resulting conformational alterations in DNA have critical consequences for their antitumor effects.     

Conformation, recognition by high mobility group domain proteins, and nucleotide excision repair of DNA intrastrand cross-links of novel antitumor trinuclear platinum complex BBR3464

The new antitumor trinuclear platinum compound [(trans-PtCl(NH(3))(2))(2)mu-trans-Pt(NH(3))(2)(H(2)N(CH(2))(6)NH(2))(2)](4+) (designated as BBR3464) is currently in phase II clinical trials. DNA is generally considered the major pharmacological target of platinum drugs. As such it is of considerable interest to understand the patterns of DNA damage. The bifunctional DNA binding of BBR3464 is characterized by the rapid formation of long range intra- and interstrand cross-links. We examined how the structures of the various types of the intrastrand cross-links of BBR3464 affect conformational properties of DNA, and how these adducts are recognized by high mobility group 1 protein and removed from DNA during in vitro nucleotide excision repair reactions. The results have revealed that intrastrand cross-links of BBR3464 create a local conformational distortion, but none of these cross-links results in a stable curvature. In addition, we have observed no recognition of these cross-links by high mobility group 1 proteins, but we have observed effective removal of these adducts from DNA by nucleotide excision repair. These results suggest that the processing of the intrastrand cross-links of BBR3464 in tumor cells sensitive to this drug may not be relevant to its antitumor effects. Hence, polynuclear platinum compounds apparently represent a novel class of platinum anticancer drugs acting by a different mechanism than cisplatin and its analogues.     

Glutathione induces cellular resistance against cationic dinuclear platinum anticancer drugs

The sulfur-containing tripeptide glutathione (GSH) is one of the most abundant molecules in cells. Elevated levels of GSH render some types of cancer cells resistant against well-known platinum anti-cancer drugs such as cisplatin and carboplatin. Platinum complexes are often very reactive towards the cysteine residue of GSH, which detoxifies these compounds by a rapid binding mechanism. Clearly, this resistance mechanism poses a severe obstacle to any new platinum drugs designed to overcome cisplatin resistance. In the present study the cytotoxicity of dinuclear platinum compounds of the 1,1/t,t type, as developed by Farrell, is determined in human ovarium A2780 cells and in the cisplatin-resistant cell line A2780cisR, which possesses elevated levels of GSH. Further, the effect of depletion of GSH levels by L-buthionine-S,R-sulfoximine (L-BSO) in A2780cisR was investigated. The experiments show that detoxification by GSH is an effective resistance mechanism against dinuclear platinum compounds. However, the dinuclear complexes are less sensitive towards detoxification compared to cisplatin. This is probably because of the rapid binding of dinuclear cationic complexes to DNA. Compared to cisplatin, the rapid binding to DNA reduces the time during which the drug molecules are exposed to GSH in the cytosol. The reaction of a representative dinuclear compound with glutathione (pH 7, 37 degrees C) was studied in detail by 195Pt NMR. The dinuclear complex BBR3005 ([trans-PtCl(2)(NH(3))(2)(mu-H(2)N(CH(2))(6)NH(2))](2+), abbreviated as 1,1/t,t n=6), follows different pathways in the reaction with GSH, depending on the molar ratio of the reactants. When reacted in stoichiometric amounts (1:1), first a chloride on each platinum is replaced by a sulfur, forming a PtN(3)S product at -2977 ppm. After 2-3 h, this intermediate reacts further to form a sulfur-bridged N(3)Pt-S-PtN(3) species as the main product at -2811 ppm. When BBR3005 is reacted with GSH in a ratio of 1:4, the sulfur-bridged species is not observed. Instead, the final product is trans-Pt(GS)(2)(NH(3))(2) (at -3215 ppm); the same product appears if GSH is reacted with trans-PtCl(2)(NH(3))(2). Apparently, GSH first replaces the chlorides and subsequently degrades the dinuclear compound by replacement of the diaminealkyl linker.     

DNA interstrand cross-links of the novel antitumor trinuclear platinum complex BBR3464. Conformation,recognition by high mobility group domain proteins,and nucleotide excision repair

The novel phase II antitumor polynuclear platinum drug BBR3464 ([(trans-PtCl(NH(3))(2))(2)(mu-trans-Pt(NH(3))(2)(NH(2)(CH(2))(6)NH(2))(2))](NO(3))(4)) forms intra- and interstrand cross-links (CLs) on DNA (which is the pharmacological target of platinum drugs). We examined first in our recent work how various intrastrand CLs of BBR3464 affect the conformation of DNA and its recognition by cellular components (Zehnulova, J., Kasparkova, J., Farrell, N., and Brabec, V. (2001) J. Biol. Chem. 276, 22191-22199). In the present work, we have extended the studies on the DNA interstrand CLs of this drug. The results have revealed that the interstrand CLs are preferentially formed between guanine residues separated by 2 base pairs in both the 3' --> 3' and 5' --> 5' directions. The major 1,4-interstrand CLs distort DNA, inducing a directional bending of the helix axis and local unwinding of the duplex. Although such distortions represent a potential structural motif for recognition by high mobility group proteins, these proteins do not recognize 1,4-interstrand CLs of BBR3464. On the other hand, in contrast to intrastrand adducts of BBR3464, 1,4-interstrand CLs are not removed from DNA by nucleotide excision repair. It has been suggested that interstrand CLs of BBR3464 could persist considerably longer in cells compared with intrastrand adducts, which would potentiate the toxicity of the interstrand lesions to tumors sensitive to this polynuclear drug.     

Consequences of nucleic acid conformation on the binding of a trinuclear platinum drug.

BBR3464, a charged trinuclear platinum compound, is the first representative of a new class of anticancer drugs to enter phase I clinical trials. The structure of BBR3464 is characterized by two [trans-PtCl(NH(3))(2)] units linked by a tetraamine [trans-Pt(NH(3))(2)?H(2)N(CH(2))(6)NH(2)?(2)] unit. The +4 charge of BBR3464 and the separation of the platinating units indicate that the mode of DNA binding will be distinctly different from those of classical mononuclear drugs such as cisplatin, cis-[PtCl(2)(NH(3))(2)]. The reaction of BBR3464 with three different nucleic acid conformations was assessed by gel electrophoresis. Comparison of single-stranded DNA, RNA, and double-stranded DNA indicated that the reaction of BBR3464 with single-stranded DNA and RNA was faster than that with duplex DNA, and produced more drug-DNA and drug-RNA adducts. Electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry was used to further characterize the binding modes of BBR3464 with the DNA substrates. BBR3464 binding to different nucleic acid conformations raises the possibility that the adducts of single-stranded DNA and RNA may play a role in the different antitumor efficacies of this novel drug as compared with cisplatin.     

Cellular pharmacology of polynuclear platinum anti-cancer agents

Study of the cellular pharmacology of the dinuclear platinum complexes, BBR3005 ([?trans-PtCl(NH3)2?2H2N(CH2)6NH2]2+), BBR3171 ([?cis-PtCl(NH3)2?2H2N(CH2)6NH2]2+) and the trinuclear platinum complex, BBR3464 ([?trans-PtCl(NH3)2?2 mu-?trans-Pt(NH3)2(H2N(CH2)6NH2)2?]4+) was undertaken in wild type and cisplatin-resistant L1210 murine leukemia cell lines. All complexes are potent cytotoxic agents against the wild type cell line. Only BBR3464 shows enhanced activity against the cisplatin-resistant cell line following a brief exposure. This enhanced activity is attributable, in part, to preserved accumulation, which contrasts with diminished accumulation of cisplatin and both dinuclear platinum complexes. The cisplatin-resistant cell line is relatively tolerant of DNA adducts induced by both cisplatin and BBR3464, but BBR3464 is much less affected. All complexes induce DNA interstrand cross-links. Di/trinuclear complex-induced interstrand cross-linking peaks early, suggesting rapid genomic access and interaction. Subsequent decay suggests susceptibility to DNA repair mechanisms. Peak and area-under-the-curve values for interstrand cross-linking among the complexes correlate poorly with cytotoxic effects, especially in the cisplatin-resistant cell line. This suggests that all interstrand cross-linking adducts are not equal in their cytotoxic effect, or other, non-interstrand cross-linking adducts are significant. BBR3464 has been selected for clinical development largely on the basis of results from in vivo activity and toxicity studies. These results show BBR3464 to have unique properties in the context of acquired cisplatin-resistance that enhance its candidacy as a potential anticancer agent.     

Mechanism of the membrane interaction of polynuclear platinum anticancer agents. Implications for cellular uptake

The interaction between phospholipids and polynuclear platinum drugs was studied as a mechanism model for cellular uptake of anticancer drugs. The interaction was studied by differential scanning calorimetry (DSC), 31P nuclear magnetic resonance spectroscopy (NMR), inductively coupled plasma optical emission spectroscopy (ICP-OES), and electrospray ionization mass spectrometry (ESI-MS). The transition temperature, enthalpy, and entropy of negatively charged phospholipids DPPS, DPPA, and DPPG were changed upon reaction with the trinuclear platinum complex [{trans-PtCl(NH3)2}2mu-Pt(NH3)2{H2N(CH2)6NH2}2](NO3)4 (I, BBR3464) and the dinuclear analogue [{trans-PtCl(NH3)2}mu-{(NH2)(CH2)3NH2(CH2)4(NH2)}Cl3 (II, BBR3571). This suggests that these platinum complexes interacted not only with the phosphate headgroup but also with the region of the fatty acid tail of liposomes and finally changed the fluidity of the membrane. Both noncovalent (presumably electrostatic and hydrogen bonding) and covalent interactions were involved in the reactions of the negatively charged phospholipids DPPA, DPPS, and DPPG with the highly positively charged platinum complexes. In contrast, few differences were seen for the zwitterionic phospholipids DPPC and DPPE. The binding ratio of BBR3464 to DPPA liposomes was higher than the ratio of BBR3464 to DPPS liposomes, and similar differences were seen for BBR3571. The binding ratios of the platinum complexes to negatively charged phospholipids DPPA, DPPS, and DPPG were slightly lower in a 100 mM chloride solution than in a chloride-free solution. The binding of BBR3464 and BBR3571 with the liposomes was significantly stronger than that with cis-[PtCl2(NH3)2], cisplatin. ESI-MS confirmed that the products of the incubation of BBR3464 with DPPA and DPPS correspond to chloride displacement and formation of [Pt3(NH3)6{NH2(CH2)6NH2}2(DPPA)2]2+ (1) and [Pt3(NH3)6{NH2(CH2)6NH2}2(DPPS)2]2+ (2), respectively. Similar observations were made for BBR3571. 31P NMR spectra confirmed that the site of binding for DPPA was the phosphate oxygen, whereas for DPPS, a binding site of the nitrogen of the serine side chain is indicated. Noncovalent interactions were also confirmed by use of the analogue [{Pt(NH3)3}2mu-Pt(NH3)2{H2N(CH2)6NH2}2](NO3)6 (III, 0,0,0/t,t,t). The implications of these results for the mechanism of cellular uptake of polynuclear platinum complexes are discussed.     

Comparison of cytotoxicity and cellular accumulation of polynuclear platinum complexes in L1210 murine leukemia cell lines

The antitumor activity of the trinuclear Phase I clinical agent, BBR3464, is matched by that of polyamine-linked dinuclear complexes. The cytotoxicity and cellular accumulation of three polynuclear platinum complexes: [?trans-PtCl(NH3)2?2 mu-?trans-Pt(NH3)2(H2N(CH2)6-NH2)2?]4+ (BBR3464), [?trans-PtCl(NH3)2?2(H2N(CH2)3NH2(CH2)4NH2)]3+ (BBR3571), and [?trans-PtCl(NH3)2?2(H2N(CH2)6-NH2)]2+ (BBR3005), were studied in a series of murine L1210 cell lines and compared with cisplatin. Besides murine L1210 cell lines sensitive (/0) and resistant (/DDP) to cisplatin, the efficacy of the compounds in a cell line rendered resistant to BBR3464 (/3464) was examined. Finally, to examine possible uptake pathways of these novel charged complexes, cytotoxicity in a cell line resistant to the polyamine synthesis inhibitor, methylglyoxal-bis(guanylhydrazone) (/MGBG), was studied. Cytotoxicity profiles of BBR3571 most closely matched that of BBR3464. Both agents showed significantly reduced cytotoxicity in L1210/ BBR3464. The cytotoxicity of neither agent was affected by the polyamine uptake-deficient cell line and indeed both complexes showed significantly enhanced cytotoxicity in L1210/MGBG relative to wild-type L1210/0. The cellular uptake of both BBR3464 and BBR3571 was enhanced in L1210/DDP. These studies suggest that the chemical feature of a diamine linker containing an internal charge contributes significantly to the anticancer profiles of both the trinuclear platinum complex, BBR3464, which incorporates a charged platinum into a diamine linker, and the dinuclear platinum complex, BBR3571, which incorporates only a naturally occurring polyamine as diamine linker.     

Kinetic study of azole-bridged dinuclear platinum(II) complexes reacting with a hairpin-stabilized double-stranded oligonucleotide

The cytotoxic dinuclear platinum(II) complexes [[cis-Pt(NH(3))(2)](2)(mu-OH)(mu-pz)](NO(3))(2) (pz=pyrazolate) (1) and [[cis-Pt(NH(3))(2)](2)(mu-OH)(mu-1,2,3-ta-N1,N2)](NO(3))(2) (1,2,3-ta=1,2,3-triazolate) (2), were allowed to react with the hairpin-stabilized double-stranded oligonucleotide d(TATGGCATT(4)ATGCCATA), to determine the amounts of intrastrand and interstrand DNA adducts. The reaction kinetics was investigated by reversed-phase HPLC, and the resulting products were analyzed using mass spectroscopy combined with enzymatic digestion, and Maxam-Gilbert sequencing. The reaction of 1 results in the formation of the 1,2-intrastrand d(GG) adduct as the major final product. The two most abundant products of 2 were identified as isomeric 1,2-intrastrand d(GG) adducts differing probably in platinum coordination to the triazole ring. No GG-interstrand crosslinks were detected with either compound. d(GGC)-d(GCC) sequences of DNA do thus not appear to represent significant targets for forming interstrand crosslinks with either 1 or 2.     

Thermodynamic properties of duplex DNA containing a site-specific d(GpG) intrastrand crosslink formed by an antitumor dinuclear platinum complex

Bifunctional polynuclear platinum compounds represent a novel class of metal-based antitumor drugs which are currently undergoing preclinical development. A typical agent is [(trans-PtCl(NH(3))(2))(2)H(2)N(CH(2))(4)NH(2)]Cl(2) (1,1/t,t), which coordinates to bases in DNA and forms various types of covalent crosslinks. It also forms a 1,2-d(GpG) intrastrand adduct, the equivalent of the major DNA lesion of 'classical' cisplatin. In the present study differential scanning calorimetry and spectroscopic techniques were employed to characterize the influence of this crosslink on the thermal stability and energetics of 20 bp DNA duplexes site-specifically modified by 1,1/t,t. Thermal denaturation data revealed that the crosslink of 1,1/t,t reduced thermal and thermodynamical stability of the duplex noticeably more than that of 'classical' cisplatin. The energetic consequences of the intrastrand crosslink at the d(GG) site are discussed in relation to the structural distortions induced by this adduct in DNA and to its recognition and binding by HMG domain proteins. It has been suggested that the results of the present work are consistent with different DNA binding modes of cisplatin and polynuclear bifunctional DNA-binding drugs, which might be relevant to their distinct biological effectiveness.     

Synthesis and DNA conformational changes of non-covalent polynuclear platinum complexes

Polynuclear platinum compounds demonstrate many novel phenomena in their interactions with DNA and proteins as well as novel anti-cancer activities. Previous studies indicated that the high positive charge and the non-coordinated "central linker" of the polynuclear compounds could have major contributions to these features. Therefore, a series of non-covalent polynuclear platinum complexes, [[Pt(NH(3))(3)](2)-mu-Y](n+) (Y=polyamine linker or [trans-Pt(NH(3))(2)(H(2)N(CH(2))(6)NH(2))(2)]) was synthesized and the DNA interactions of these platinum complexes were investigated. The conformational changes induced by these compounds in polymer DNA were studied by circular dichroism and the reversibility of the transition was tested by subsequent titration with the DNA intercalating agent ethidium bromide (EtBr). Fluorescent quenching was also used to assess the ability of EtBr to intercalate into A and Z-DNA induced by the compounds. The non-covalent polynuclear platinum complexes induced both B-->A and B-->Z conformational changes in polymer DNA. These conformational changes were partially irreversible. The platinum compound with the spermidine linker, [[Pt(NH(3))(3)](2)-mu-spermidine-N(1),N(8)]Cl(5).2H(2)O, is more efficient in inducing the conformational changes of DNA and it is less reversible than complexes with other linkers. The melting point study showed that the non-covalent polynuclear platinum complexes stabilized the duplex DNA and the higher the electrical charge of the complexes the greater the stabilization observed.     

DNA modifications by a novel bifunctional trinuclear platinum phase I anticancer agent.

The DNA-binding profile of a novel, trinuclear platinum Phase I clinical agent (BBR3464) is summarized. The structure of BBR3464 is best described as two trans-[PtCl(NH3)2] units linked by a tetra-amine [trans-Pt(NH3)2{H2N(CH2)6NH2}2]2+ unit. The +4 charge of BBR3464, the presence of at least two Pt coordination units capable of binding to DNA, and the consequences of such DNA binding are remarkable departures from the cisplatin structural paradigm. The chemical and biological features argue that the drug should be considered the first clinical representative of an entirely new structural class of DNA-modifying anticancer agents. The high charge on BBR3464 facilitates rapid binding to DNA with a t1/2 of approximately 40 min, significantly faster than the neutral cisplatin. The melting temperature of DNA adducted by BBR3464 increased at low ionic strength but decreased in high salt for the same rb. This unusual behavior is in contrast to that of cisplatin. BBR3464 produces an unwinding angle of 14 degrees in negatively supercoiled pSP73 plasmid DNA, indicative of bifunctional DNA binding. Quantitation of interstrand DNA-DNA cross-linking in plasmid pSP73 DNA linearized by EcoRI indicated approximately 20% of the DNA to be interstrand cross-linked. While this is significantly higher than the value for cisplatin, it is, interestingly, lower than that for dinuclear platinum compounds such as [{trans-PtCl(NH3)2}2H2N(CH2)6NH2]2+ (BBR3005) where interstrand cross-linking efficiency may be as high as 70-90%. Either the presence of charge in the linker backbone or the increased distance between platinating moieties may contribute to this relatively decreased ability of BBR3464 to induce DNA interstrand cross-linking. Fluorescence experiments with ethidium bromide were consistent with the formation of long-range delocalized lesions on DNA produced by BBR3464. The sequence preference for BBR3464 on plasmid DNA was determined to the exact base pair by assaying extension of the polynucleotide by VentR(exo+) DNA polymerase. Strong sequence preference for single dG or d(GG) sites was suggested. The presence of relatively few blocks on DNA in comparison to either cisplatin or BBR3005 was indicative of high sequence selectivity. The following appropriate sequence where stop sites occur was chosen: [sequence: see text] molecular modeling on 1,4 interstrand (G'30 to G33) and 1,5 intrastrand (G33 to G29) cross-links further confirmed the similarity in energy between the two forms of cross-link. Finally, immunochemical analysis confirmed the unique nature of the DNA adducts formed by BBR3464. This analysis showed that antibodies raised to cisplatin-adducted DNA did not recognize DNA modified by BBR3464. In contrast, DNA modified by BBR3464 inhibited the binding of antibodies raised to transplatin-adducted DNA. Thus, the bifunctional binding of BBR3464 contains few similarities to that of cisplatin but may have a subset of adducts recognized as being similar to the transplatinum species. In summary, the results point to a unique profile of DNA binding for BBR3464, strengthening the original hypothesis that modification of DNA binding in manners distinct from that of cisplatin will also lead to a distinct and unique profile of antitumor activity.     

Sequence-dependent conformational changes in DNA induced by polynuclear platinum complexes

In this work, the B-->Z transition of poly(dG-dC).poly(dG-dC) and the B-->A transition of poly(dG).poly(dC) and of calf thymus (CT) DNA fragments modified by antitumor bifunctional polynuclear platinum complexes were investigated by circular dichroism (CD). The transition from the B- to Z-form of DNA was inducible with all three compounds studied, as indicated by an inversion of the B-form spectra. The B-->A transition in poly(dG).poly(dC) was induced easily by platinum complex binding alone, while the B-->A transition in CT DNA was induced by ethanol but inhibited by coordination of all polynuclear platinum compounds used here. It was shown that the compound [?cis-PtCl(NH3)2?2 mu-?H2N(CH2)6NH2?] (NO3)2 (1,1/c,c) was most effective at inhibiting the B-->A transition in CT DNA, and [?trans-PtCl(NH3)2?2 mu-?trans-Pt(NH3)2(H2N(CH2)6NH2)2?] (NO3)4 (1,0,1/t,t,t) was least effective, while the effectiveness of [?trans-PtCl(NH3)2?2 mu-?H2N(CH2)6NH2?] (NO3)2 (1,1/t,t) fell between the two. This corresponded to the relative amounts of interstrand crosslinks in double-stranded DNA caused by each compound.     

Cross-links of quadruplex structures from human telomeric DNA by dinuclear platinum complexes show the flexibility of both structures

The folding of AG(3)(T(2)AG(3))(3) was investigated in the presence of Na(+) or K(+) ions, by using the dinuclear platinum complexes [{trans-PtCl(NH(3))(2)}(2)H(2)N(CH(2))(n)NH(2)]Cl(2) (n = 2 or 6). AG(3)(T(2)AG(3))(3) has been previously found to adopt two different quadruplex structures: the antiparallel one in a solution containing Na(+) and the parallel one in a K(+)-containing crystal. The two structures are strikingly distinct and are not expected to form the same platinum cross-links. Therefore, characterization of the cross-links formed with platinum complexes in solution allowed the predominant conformation(s) to be identified. The bases coordinating the platinum atoms were identified by chemical and 3'-exonuclease digestions. The observed cross-links showed that the parallel structure exists in solution whatever the cation and confirmed the existence of the antiparallel structure in the presence of both cations as previously reported from cross-linking experiments of AG(3)(T(2)AG(3))(3) by mononuclear platinum complexes. Furthermore, the major platinum cross-links were unexpectedly formed between two guanines belonging to the same G-quartet. Their formation was rationalized using molecular dynamics simulations in implicit solvent of the two quadruplex structures. It was shown that they were flexible, allowing some guanines to leave reversibly the top G-quartet and thus rendering their N(7) atom accessible to platinum complexes. Our results also suggest that the human telomere sequence could be a target for such platinum complexes.     

Deoxyribonuclease I footprinting reveals different DNA binding modes of bifunctional platinum complexes

Deoxyribonuclease I (DNase I) footprinting methodology was used to analyze oligodeoxyribonucleotide duplexes containing unique and single, site-specific adducts of trinuclear bifunctional platinum compound, [{trans-PtCl(NH3)2}2 mu-trans-Pt(NH3)2{H2N(CH2)6NH2}2]4+ (BBR3464) and the results were compared with DNase I footprints of some adducts of conventional mononuclear cis-diamminedichloroplatinum(II) (cisplatin). These examinations took into account the fact that the local conformation of the DNA at the sites of the contacts of DNase I with DNA phosphates, such as the minor groove width and depth, sequence-dependent flexibility and bendability of the double helix, are important determinants of sequence-dependent binding to and cutting of DNA by DNase I. It was shown that various conformational perturbations induced by platinum binding in the major groove translated into the minor groove, allowing their detection by DNase I probing. The results also demonstrate the very high sensitivity of DNase I to DNA conformational alterations induced by platinum complexes so that the platinum adducts which induce specific local conformational alterations in DNA are differently recognized by DNase I.