Versatile analytical methodology for evaluation of drug-like properties of potentially multi-targeting anticancer metallodrugs.

Using inductively coupled plasma mass spectrometry (in combination with ultrafiltration) and microemulsion electrokinetic chromatography, the drug properties of two new, potentially multi-targeting Ru(III) and Pt(IV) compounds, containing biologically active ligands, were evaluated. The ruthenium complex with bexarotene was shown to bind to albumin faster than to transferrin and exhibits much the same (to albumin) binding profile in human serum. The Pt(IV)-lonidamine complex interacts with albumin relatively slowly but possesses high stability and lipophilicity (log P 1.62), which makes it possible the cellular uptake in a free (of proteins) form. Although both examined compounds display a moderate solubility (below 10-4 M), this stands compatible with their nanomolar cytotoxic activities. The Ru(III) compound, whose active moiety is a complexed anion, is deemed promising to be loaded on nanoscale anion-exchangers with the aim of controlled delivery.

Influence of the Number of Axial Bexarotene Ligands on the Cytotoxicity of Pt(IV) Analogs of Oxaliplatin.

We present the synthesis and cytotoxic potencies of new Pt(IV) complexes with bexarotene, an anticancer drug that induces cell differentiation and apoptosis via selective activation of retinoid X receptors. In these complexes bexarotene is positioned as an axial ligand. The complex of one bexarotene ligand attached to Pt(IV) oxaliplatin moiety was potent whereas its counterpart carrying two bexarotene ligands was inactive.

Protein ruthenation and DNA alkylation: chlorambucil-functionalized RAPTA complexes and their anticancer activity.

Chemotherapeutics for the treatment of tumorigenic conditions that feature novel modes of action are highly sought after to overcome the limitations of current chemotherapies. Herein, we report the conjugation of the alkylating agent chlorambucil to the RAPTA scaffold, a well-established pharmacophore. While chlorambucil is known to alkylate DNA, the RAPTA complexes are known to coordinate to amino acid side chains of proteins. Therefore, such a molecule combines DNA and protein targeting properties in a single molecule. Several chlorambucil-tethered RAPTA derivatives were prepared and tested for their cytotoxicity, stability in water and reactivity to protein and DNA substrates. The anticancer activity of the complexes is widely driven by the cytotoxicity of the chlorambucil moiety. However, especially in the cisplatin-resistant A2780R cells, the chlorambucil-functionalized RAPTA derivatives are in general more cytotoxic than chlorambucil and also a mixture of chlorambucil and the parent organoruthenium RAPTA compound. In a proof-of-principle experiment, the cross-linking of DNA and protein fragments by a chlorambucil-RAPTA derivative was observed.