Mono and dinuclear phosphinegold(I) sulfanylcarboxylates: influence of nuclearity and substitution of PPh3 for PEt3 on cytotoxicity.

Gold complexes of the type [Au(PEt3)(Hxspa)] were prepared by reacting triethylphosphinegold(I) chloride in ethanol/water (8:1) with the 3-(aryl)-2-sulfanylpropenoic acids H2xspa [x=p=3-phenyl-; f=3-(2-furyl)-; t=3-(2-thienyl)-; py=3-(2-pyridyl); Clp=3-(2-Chlorophenyl)-; -o-mp=3-(2-methoxyphenyl)-; -p-mp=3-(4-methoxyphenyl)-; -o-hp=3-(2-hydroxyphenyl)-; -p-hp=3-(4-hydroxyphenyl)-; -diBr-o-hp=3-(3,5-dibromo-2-hidroxyphenyl-); spa=2-sulfanylpropenoato] or 2-cyclopentylidene-2-sulfanylacetic acid (H2cpa) and KOH in a 1:1:1 mole ratio. The compounds were characterized by IR spectroscopy and FAB mass spectrometry and by (1)H, (13)C and (31)P NMR spectroscopy. The in vitro antitumor activity of these and of the previously described dinuclear [(AuPEt3)2(xspa)] complexes against the HeLa-229, A2780 and A2780cis cell lines was determined and compared with those of the analogous PPh3 complexes. The results show that the substitution of the PPh3 ligand by PEt3 is particularly effective in increasing the cytotoxicity of the dinuclear [(AuPR3)2(xspa)] complexes, giving rise to compounds that are significantly more active than cisplatin against the aforementioned cell lines. In addition, and as a preliminary test for nephrotoxicity, the cytotoxicity of the most active compounds against the normal renal LCC-PK1 cell line was evaluated and compared with that of cisplatin.

Quantitative analysis of the effects of photoswitchable distance constraints on the structure of a globular protein.

Photoswitchable distance constraints in the form of photoisomerizable chemical cross-links offer a general approach to the design of reversibly photocontrolled proteins. To apply these effectively, however, one must have guidelines for the choice of cross-linker structure and cross-linker attachment sites. Here we investigate the effects of varying cross-linker structure on the photocontrol of folding of the Fyn SH3 domain, a well-studied model protein. We develop a theoretical framework based on an explicit-chain model of protein folding, modified to include detailed model linkers, that allows prediction of the effect of a given linker on the free energy of folding of a protein. Using this framework, we were able to quantitatively explain the experimental result that a longer, but somewhat flexible, cross-linker is less destabilizing to the folded state than a shorter more rigid cross-linker. The models also suggest how misfolded states may be generated by cross-linking, providing a rationale for altered dynamics seen in nuclear magnetic resonance analyses of these proteins. The theoretical framework is readily portable to any protein of known folded state structure and thus can be used to guide the design of photoswitchable proteins generally.

Structural and quantum chemical studies of 8-aryl-sulfanyl adenine class Hsp90 inhibitors.

Hsp90 chaperones play a critical role in modulating the activity of many cell signaling proteins and are an attractive target for anti-cancer therapeutics. We report here the structures of the water soluble 8-aryl-sulfanyl adenine class Hsp90 inhibitors, 1 (PU-H71) and 2 (PU-H64), in complex with the N-terminal domain of human Hsp90alpha. The conformation of 1 when bound to Hsp90 differs from previously reported 8-aryl adenine Hsp90 inhibitors including 3 (PU24FCl). While the binding mode for 3 places the 2'-halide of the 8-aryl group on top of the adenine ring, for 1 and 2, we show that the 2'-halide is rotated approximately 180 degrees away. This difference explains the opposing trends in Hsp90 inhibitory activity for the 2'-halo derivatives of the 3',4',5'-trimethoxy series where Cl > Br > I compared to the 4',5'-methylenedioxy series where I > Br > Cl. We also present quantum chemical calculations of 2 and its analogues that illuminate their basis for Hsp90 inhibition. The calculated conformation of 2 agreed well with the crystallographically observed conformations of 1 and 2. The predictive nature of the calculations has allowed the exploration of additional derivatives based on the 8-aryl adenine scaffold.

Suramin analogues with a 2-phenylbenzimidazole moiety as partial structure; potential anti HIV- and angiostatic drugs, 2: Sulfanilic acid-, benzenedisulfonic acid-, and naphthalenetrisulfonic acid analogues.

The synthesis of suramin analogues bearing a 2-phenyl-benzimidazole moiety is described. Aminoarene sulfonic acids 2a-e are acylated with 3,4-dinitrobenzoyl chloride 3 yielding the amides 4a-e which are hydrogenated to the corresponding diamines 5a-e. These are treated with 3-nitrobenzaldehyde, yielding the azomethines 7a-e and their isomers 8a-e and 9a-e. Key step in the synthesis of the target compounds 12a-e is the oxidation of the azomethines with oxygen to the benzimidazoles 10a-e. These are hydrogenated to the amines 11a-e reacting with phosgene to yield the symmetric ureas 12a-e. Results of the anti-HIV, cytostatic, and antiangiogenic screening are presented.