Cytotoxic effects of gold(III) complexes on established human tumor cell lines sensitive and resistant to cisplatin.

Gold(III) complexes, isostructural and isoelectronic with platinum(II) complexes, are potentially attractive as anticancer agents. We have synthesized a group of square planar gold(III) complexes, all containing at least two gold-chloride bonds in cis-position, and tested their in vitro cytotoxicity on a panel of established human tumor cell lines. Remarkably, all these compounds showed significant cytotoxic effects. In particular, the complexes containing the salycilaldiminate ligand induced tumor cell growth inhibitory effects comparable to or even greater than cisplatin. All gold(III) complexes substantially retained their antitumor potency against two cisplatin-resistant tumor cell lines (CCRF-CEM/R leukemia and A2780/R ovarian carcinoma); only minimal cross-resistance with cisplatin was observed. When considering the mechanism of action, it is reasonable to assume that the cytotoxicity of these gold(III) complexes derives from DNA binding. Preliminary spectroscopic results are consistent with this hypothesis; indeed, circular dichroism experiments show that both the salycilaldiminate- and the pyridine-containing gold(III) complexes bind calf thymus DNA in vitro and alter reversibly its B-type solution conformation. These results, however, must be treated with caution; solution studies indicate that gold(III) compounds are poorly stable under physiological conditions, possibly implying that, when injected, only a small amount will reach, unchanged, the DNA target. The results of our investigations are discussed in the perspective of future work on the cytotoxic and antitumor properties of gold(III) compounds.

Biological properties of two gold(III) complexes: AuCl3(Hpm) and AuCl2(pm).

The reactivity in solution of two recently characterized gold(III) complexes, AuCl3(Hpm) and AuCl2(pm), has been investigated in view of their potential use as anti-cancer agents. In water, both compounds undergo relatively fast hydrolysis of the bound chlorides without loss of the heterocycle ligand; the process is much faster within a physiological buffer. When the two gold(III) complexes react with proteins like albumin or transferrin, reduction of gold(III) to gold(I) and/or hydrolysis is observed. On the other hand, both complexes bind rapidly and tightly to either polynucleotides or calf thymus DNA, with gold remaining in the +3 oxidation state. Circular dichroism investigations reveal a large perturbation of DNA conformation upon gold(III) binding; preferential binding to GC sequences is shown. Cytotoxicity studies on a number of tumor cell lines demonstrate a good activity of these gold(III) complexes compared to cisplatin. However, quick hydrolysis and/or reduction of these compounds under physiological conditions may represent a severe limitation to their use.