Salmon sperm DNA, treated with the antitumor agent cis-diamminedichloroplatinum(II) (cis-DDP), was enzymatically degraded to (oligo)nucleotides. Four Pt-containing products were identified by 1H NMR after preparative chromatography on a diethylaminoethyl-Sephacel column at pH 8.8. In all identified adducts, comprising approximately 90% of the total Pt in the DNA, Pt was linked to the N7 atoms of the nucleobases guanine and adenine. The two major adducts were cis-Pt(NH3)2d(pGpG) and cis-Pt-(NH3)2d(pApG), both derived from intrastrand cross-links of cis-DDP on neighboring nucleobases. Only the d(pApG) but not the d(pGpA) adduct could be detected. Two minor adducts were Pt(NH3)3dGMP, resulting from monofunctionally bound cis-DDP to guanine, and cis-Pt(NH3)2d(GMP)2, originating from interstrand cross-links on two guanines as well as from intrastrand cross-links on two guanines separated by one or more bases. For analytical purposes we developed an improved method to determine cis-DDP adducts. Routinely, 40-micrograms samples of enzymatically degraded cis-DDP-treated DNA are now analyzed by separation of the mononucleotides and Pt-containing (oligo)nucleotides on the anion-exchange column Mono Q (FPLC) at pH 8.8 (completed within 14 min) and subsequent determination of the Pt content in the collected fractions by atomic absorption spectroscopy. The method was used to optimize the digestion conditions for cis-DDP-treated DNA. In kinetic studies on the formation of the various adducts, a clear preference of the Pt compound to react with guanines occurring in the base sequence d(pGpG) was established.
A 500, 400 and 300 MHz proton NMR study of the reaction product of cis-Pt(NH3)2Cl2 or cis-[Pt(NH3)2 (H2O)2] (NO3)2 with the deoxydinucleotide d(GpG): cis-[Pt(NH3)2 d(GpG)] was carried out. Complete assignment of the proton resonances by decoupling experiments and computer simulation of the high field part of the spectrum yield proton-proton and proton-phosphorus coupling constants of high precision. Analysis of these coupling constants reveal a 100% N (C3'-endo) conformation for the deoxyribose ring at the 5'-terminal part of the chelated d(GpG) moiety. In contrast, the 3'-terminal -pG part of the molecule displays the normal behaviour for deoxyriboses: the sugar ring prefers to adopt an S (C2'-endo) conformation (about 70%). Extrapolating from this model compound, it is suggested that Pt chelation by a -dGpdG- sequence of DNA would require a S to N conformational change of one deoxyribose moiety as the main conformational alteration and lead to a kink in one strand of the double-helical structure of DNA.
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