Characterization of sterically stabilized cisplatin liposomes by nuclear magnetic resonance.

Extensive scientific efforts are directed towards finding new and improved platinum anticancer agents. A promising approach is the encapsulation of cisplatin in sterically stabilized, long circulating, PEGylated 100 nm liposomes. This liposomal cisplatin (STEALTH cisplatin, formerly known as SPI-77) shows excellent stability in plasma and has a longer circulation time, greater efficacy and lower toxicity than much free cisplatin. However, so far, the physicochemical characterization of STEALTH cisplatin has been limited to size distribution, drug-to-lipid ratio and stability. Information on the physical state of the drug in the liposome aqueous phases and the drug's interaction with the liposome membrane has been lacking. This study was aimed at filling this gap. We report a multinuclear NMR study in which several techniques have been used to assess the physical nature of cisplatin in liposomal formulations and if and to what extent the drug affects the liposome phospholipids. Since NMR detects only the soluble cisplatin in the liposomes and not the insoluble drug, combining NMR and atomic absorption data enables one to determine how much of the encapsulated drug is soluble in the intraliposomal aqueous phase. Our results indicate that almost all of the cisplatin remains intact during the loading process, and that the entire liposomal drug is present in a soluble form in the internal aqueous phase of the liposomes.

Effects of monofunctional platinum binding on the thermal stability and conformation of a self-complementary 22-mer.

We investigated the effect of various monofunctional platinum complexes on the thermal stability and conformation of a self-complementary 22-mer duplex oligonucleotide by means of CD and UV melting profiles. We studied several families of triamine complexes of the general formula PtA2AmCl where A2=(NH3)2 and ethylenediamine and where Am=N1-4-methyl-pyridine, N7-guanosine, and 9-ethyl-guanine. Platination by the N1-4-methyl-pyridine and 9-ethyl-guanine complexes led to a decrease in the Tm of the oligonucleotide by 2-11.5 degrees C while platination with the N7-guanosine complexes led to a rise in the melting temperature of the oligonucleotides by 4.5 degrees C. A similar inverse correlation between the two groups of platinum compounds was found in the CD spectra. In all cases, the cis isomer had a more pronounced effect on both the melting curve and the CD spectrum. The cis isomer was found to have a more destabilizing effect than its trans counterpart. This indicates that the cis geometry in fact forces a greater structural constraint on the backbone of the double helix. We have also found that the sugar of the guanosine has a significant influence on both the Tm and CD spectra; the sugar moiety contributes to the stability of the double helix, probably through the formation of hydrogen bonds.

Monofunctional platinum amine complexes destabilize DNA significantly.

Both cis-[Pt(NH3)2(4-Me-Py)Cl]+ and trans-[Pt(NH3)2(4-Me-Py)Cl]+ bind DNA covalently at the N7 site of guanine residues forming mono-dentate adducts. However, like cisplatin and transplatin, only the cis isomer has anti-cancer activity, whereas the trans-isomer does not. In order to understand the molecular basis of the different activities associated with cis-[Pt(NH3)2(4-Me-Py)Cl]+ and trans-[Pt(NH3)2(4-Me-Py)Cl]+, the interactions of these two platinum compounds with the DNA heptamer CCTG*TCC:GGACAGG duplex (G* is the platinated guanine) have been examined. The reaction rate of cis-[Pt(NH3)2(4-Me-Py)Cl]+ with the single-stranded CCTGTCC is significantly faster than that of the trans isomer. The solution structure of the platinum-DNA adducts has been studied by two-dimensional NMR spectroscopy. Both the cis-platinum adducts and the trans-platinum adducts destabilize the DNA duplex significantly. The melting temperature (Tm) of the platinated heptamer duplex is estimated to be 10 degrees C lower than for the unplatinated duplex by NMR. At 2 degrees C, the base pairs located on the 5' side of the oligonucleotide, beyond the platinum lesion site, are disrupted. Over time, the platinum-DNA complex decomposes and the cis-[Pt(NH3)2(4-Me-Py)] platinum complex is gradually detached from DNA. No interstrand crosslinking is observed. The biological implications of the structural studies are discussed.