The binding affinity of HMG1 protein to DNA modified by cis-platin and its analogs correlates with their antitumor activity.

The antitumor activity of cis-platin is believed to result from its interaction with cellular DNA and subsequent processing of DNA adducts by damage recognition proteins. Among them are the high mobility group (HMG) proteins 1 and 2, which have been hypothesized to mediate the effect of cis-platin. One possibility suggests that the tight binding of HMG1 to DNA adducts blocks the repair of damaged DNA. In order to further evaluate such a mechanism, several cis-platinum complexes with known antitumor activity have been used to treat DNA and the affinity of HMG1 to the DNA adduct induced by each drug was determined. The dissociation constants for the complexes of HMG1 with the platinated probe were obtained by gel mobility shift assays. The antitumor activity of the tested platinum compounds was found to correlate with the binding affinity of HMG1 to the respective drug-DNA adduct. These findings support the view that HMG1 contributes to cytotoxicity of cis-platin by shielding damaged DNA from repair. In addition, they offer a fast test for screening new platinum compounds for antitumor activity.

Unusual reactivity of cytotoxic cis-dihydrazide Pt(II) complexes in aqueous solution.

Complexes of the general structure cis-[PtX(2)(hydrazide)(2)] and cis-[PtX(2)NH(3)(hydrazide)], where X=Cl(-), Br(-) and I(-), and hydrazide=cyclohexylcarboxylic acid hydrazide (chcah), cyclopentylcarboxylic acid hydrazide (cpcah), 3-aminocyclohexanspiro-5-hydantoin (achsh) and 3-aminocyclopentanspiro-5-hydantoin (acpsh), were investigated with respect to aqueous stability, DNA platination rates and cytotoxic activity on a panel of seven human cancer cell lines as well as a cisplatin-resistant cell line. Stabilities in aqueous solution, determined by RP-HPLC and UV-Vis methods, were highly dependent on the type of halide ligand, with stability decreasing in the order I(-)>Cl(-)>Br(-). Added chloride (100 mM) only stabilized the dichloro-Pt(II) complexes containing the hydrazide as part of a hydantoin ring (i.e., achsh). Platination of calf thymus DNA determined by AAS was most rapid with dichloro-Pt(II) complexes containing achsh ligand. The mixed-amine dichloro-Pt(II) complexes with either chcah or cpcah ligands also platinated DNA >80%, but at a slower rate, while dihydrazide dichloro-Pt(II) complexes with either chcah or cpcah ligands resulted in <25% DNA platination at 24 h. cis-[PtX(2)(hydrazide)(2)], where hydrazide=chcah or cpcah, were the most potent compounds (chcah>cpcah), but activity was independent of the halide ligand (I(-)=Cl(-)=Br(-)). These complexes showed no cross-resistance with cisplatin, but they also showed little differentiation in potency over the seven cell lines. Complexes with the hydantoin ligands achsh and acpsh were inactive in all cell lines. Thus, neither stability in aqueous media nor covalent binding to DNA are correlated with biological activity, suggesting that cis-dihydrazide Pt(II) complexes act by a unique mechanism of action.

Synthesis, cytotoxicity, antibacterial and antitumor activity of platinum(II) complexes of 3-aminocyclohexanespiro-5-hydantoin.

New platinum(II) complexes of 3-aminocyclohexanespiro-5-hydantoin (achsh) were prepared and characterized. Ab initio calculation of the structure and the measurements of IR and NMR spectra of [Pt(NH(3))(achsh)Cl(2)] were also performed. Quantum-chemical and spectroscopic studies indicated a cis-square planar structure with a hydantoin ligand coordinated via the NH(2) group. The complexes were evaluated for in vitro cytotoxicity in murine erythroleukemia (MEL) cells, clone F4N, as well as for in vivo antitumor activity toward murine L1210 leukemia. The complexes exerted significantly lower in vitro and in vivo toxicities compared with those of cisplatin (cis-diamminedichloroplatinum(II), DDP). The complex [Pt(NH(3))(achsh)Cl(2)] exhibited antitumor activity against L1210 leukemia, comparable to that of cisplatin, resulting at a dose of 72 mg/kg in a %T/C (increased survival time) of 191%. This complex, as well as cisplatin, induced apoptosis in F4N cells, and exerted antibacterial activity as assessed in 10 bacterial strains.

Synthesis and cytotoxicity of platinum(II) complexes of 3-aminocyclopentanespiro-5-hydantoin and 3-aminocycloheptanespiro-5-hydantoin.

Four new platinum(II) complexes of 3-aminocyclopentanespiro-5-hydantoin (acpsh) and 3-aminocycloheptanespiro-5-hydantoin (achpsh) were synthesized and characterized by elemental analysis, IR and 1NMR spectra. The spectral analyses indicated a cis-square planar structure of the complexes with ligands coordinated via the NH2 group. The complexes were evaluated for in vitro cytotoxicity in murine erythroleukemia (MEL) cells, clone F4N, using cell-growth and macromolecular synthesis assay. The compounds, with exception of [Pt(NH3)(achpsh)Cl2] (IV), exhibited much lower cytotoxicity than that of cisplatin (DDP). Compound IV was nearly as cytotoxic as DDP. The new complexes exerted low antibacterial activity as assessed by seven bacterial strains.

Correlation between HSP90 induction kinetics in murine leukemia cells and the amount of cisplatin over a wide range of cytostatic concentrations.

The induction of HSP90 in murine erythroleukemia cells, clone F4 N, by cisplatin (DDP) was examined using indirect immunofluorescence and avidin-biotin technique, and compared with cisplatin cytotoxicity. A reverse dependence of HSP90 induction time was found on a wide range of cisplatin concentrations (0.5-10 microM), which proved to be cytostatic up to 48 h of continuous treatment. Thus, the observed induction pattern of HSP90 in F4 N cells strictly correlated with their high tolerance toward DDP. This indicates that HSP90 might be responsible, at least in part, for cisplatin resistance of F4 N cells.