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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Platinum anti-cancer complexes

Wheate, Nial Joseph, Chemistry, Australian Defence Force Academy, UNSW January 2001 (has links)
[Formulae and special characters can only be approximated here. Please see the pdf version of the Abstract for an accurate reproduction.] Several inert platinum complexes were synthesised: [(en)Pt([special character]-dpzm)2Pt(en)]4+, [{Pt(dien)}2[special character]-dpzm]4+, [{Pt(dien)}2[special character]-H2N-(CH2)6-NH2]4+, cis-[(NH3)2Pt([special character]--dpzm)2Pt(NH3)2]4+, trans-[Pt(NH3)2([special character]-dpzm)2]2+. Three active complexes, all with chloro ligands, were also synthesised: trans-[{Pt(NH3)Cl2}2[special character]-dpzm)], trans-[{Pt(NH3)2Cl}2[special character]-dpzm]2+ (di-Pt) and trans-[trans-{Pt(NH3)2Cl}2{trans-[Pt(NH3)2([special character]-dpzm)2]}]4+ (tri-Pt). 1H NMR established that multi-nuclear platinum complexes will preferentially associate in the DNA minor groove with a preference for A/T sequences, and with a binding constant [special character]-105 M-1, regardless of the charge, linking ligand, length or shape. Using [(en)Pt([special character]-dpzm)2Pt(en)]4+ and the oligonucleotide d(GC)5 it was determined that the metal complex binds G/C rich sequences also in the minor groove, but with a much reduced binding constant, 103 M-1. CD studies showed [(en)Pt([special character]-dpzm)2Pt(en)]4+ was able to induce a DNA conformation change from B-type to what appeared to be a partial Z-type. Transcription assays showed that even though the metal complex does not bind DNA covalently, it is still able to inhibit DNA transcription at particular sites. The complexes di-Pt, tri-Pt, [{Pt(dien)}2[special character]-dpzm]4+ and trans-[Pt(NH3)2([special character]-dpzm)2]2+ were tested for anti-cancer activity in the L1210 murine leukaemia cell line, and gave values of 3.8, 2.5, [special character]200 and 64 [special character]M respectively. In the cisplatin resistant line (L1210/DDP), trans-[Pt(NH3)2([special character]-dpzm)2]2+ showed an increase in activity with a drop to 32 [special character]M, while both di-Pt and tri-Pt showed decreases in activity to values of 8.8 and 3.6 [special character]M. In the human ovarian carcinoma 2008 cell line and its cisplatin resistant derivative C13[special character]5, both complexes showed good activity with values of 2.5 and 20.9 [special character]M respectively, but again both showed decreases in activity in the resistant line with values of 17.8 and 37.7 [special character]M respectively. To help explain the difference between activity of these complexes and the complexes BBR3464 and BBR3005, cell uptake and DNA interstrand cross-linking experiments were performed. The cell uptake studies showed that both di-Pt and tri-Pt are taken up by cells at very high levels, when administered at 100 [special character]M, thus indicating that the difference is unlikely to be due to large differences in cell uptake. The DNA interstrand cross-linking studies showed both complexes readily form interstrand adducts (50% interstrand cross-linking at 12 nM and 22 nM respectively, c.f cisplatin 3 [special character]M). These results suggest that the rigid nature of the dpzm linker may be affecting the DNA adducts formed, with more interstrand links being formed than BBR3464. Possibly, it is this that causes the large differences in cytotoxicity. The DNA binding of di-Pt and tri-Pt was examined with the nucleosides adenosine and guanosine and the dinucleotide d(GpG). Both complexes bound at the N7 of guanosine, but 2-fold slower than cisplatin. In addition, di-Pt bound at the N7 and either the N1 or N3 of adenosine, 7-fold slower than guanosine. Di-Pt forms a large variety of cross-links between two d(GpG) molecules, however it could not be established whether the 1,2-intrastrand adduct could be formed. Di-Pt, however, forms a 1,2-GG interstrand adduct with the oligonucleotide d(ATGCAT)2 resulting in a conformation change away from B-type DNA. The sugar pucker of the G3 nucleoside changes from 2[special character]-endo towards 3[special character]-endo, and the position of the nucleotide relative to the sugar changes from anti to syn. The ability of multi-nuclear platinum complexes to form covalent adducts in the DNA minor groove remains unclear. It appears that di-Pt can form up to 33% minor groove adducts with the oligonucleotide d(AT)5, but when added to the oligonucleotide d(GCCAAATTTCCG)2 no definite minor groove adducts are seen and the major adduct appears to be a 1,2-interstrand cross-link between the two A6's or between the G1 and G11. Finally, a study of the encapsulation of platinum complexes within cucurbit[7]uril (Q7) as a means of reducing drug toxicity was made. For complex A and di-Pt, encapsulation of the linker ligand occurred. The effect of Q7 on the rate of hydrolysis of di-Pt was at least a 3-fold reduction as compared to free di-Pt with guanosine. Studies with [{Pt(dien)}2[special character]-dpzm]4+/Q7 and the oligonucleotide d(CGCGAATTCGCG)2 showed that the metal complex could dissociate from the Q7 and associate with the oligonucleotide, where an equilibrium is achieved with 15 % of the metal complex bound to the oligonucleotide and 75 % encapsulated in Q7. Tests in the L1210 and L1210/DDP cancer cell lines showed that di-Pt/Q7 has almost the same activity compared to free di-Pt.

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